EP1273077A1 - Method and device for regulating a medium with an amplifying effect, especially a fiber optical waveguide - Google Patents

Abstract

The invention relates to a method and a device for regulating the optical amplification of a medium with an amplifying effect, especially a doped fiber optical waveguide. The intensity of the amplified spontaneous emission is used as a regulating variable for the amplification power, especially the power of a pump laser.

Description

description

Method and device for regulating a medium with a reinforcing effect, in particular an optical fiber

The invention relates to a method for regulating a gain of a medium with a reinforcing effect in an optical data transmission system, to which energy is supplied by optical or electrical means and which amplifies a light signal that passes through the medium. In addition, the invention relates to devices for carrying out the above-mentioned method.

Digital and analog data are increasingly being transmitted over long distances in the form of optical data signals in fiber optic cables. For this purpose, it is necessary to amplify the light signals, which suffer a loss of intensity in the course of their transmission path, at regular intervals. Such amplification can take place, for example, by electronically reading out the signals, then regenerating the optical signals and feeding these signals into a further transmission path. However, there is also the possibility of achieving the amplification by means of purely optical amplification, for example by means of so-called optical amplifiers, which can also be pumped remotely.

Such a data transmission link with a remote-pumped optical power amplifier is known from the applicant's patent application DE 196 22 012 AI. In this application, an optical data transmission link is shown, which consists of sections with passive transmission fibers and interposed remote-pumped distributed optical amplifiers, these optical amplifiers being constructed on the basis of active fibers which are known to contain ions from the group of rare earths are doped and obtain their amplification energy via a pump light source. ^{• •} The content of the disclosure of the above-cited patent application and the IEEE-Photonics Technology Letters, VOL.7, NO 3, March 1995, pp. 333-335, is hereby accepted in full.

One problem with such optical amplifiers is that they superimpose a noise spectrum on the information-carrying light waves. The noise components generated in this way are also amplified in subsequent amplifiers. In order to obtain the same signal quality for all channels, the same signal-to-noise ratio should be present for all wavelength channels at the end of the transmission path. Furthermore, nonlinear effects in glass fibers limit the maximum permissible channel powers. There is therefore an optimal operating state of the transmission link. In order to operate the line as close as possible to its optimal operating state, it is necessary to control the optical amplifiers as precisely as possible. Unregulated amplification of the light signals can have a negative impact on the transmission quality and increase the error rate of the digital signals.

It is therefore an object of the invention to find a method and a device for regulating the amplification of optical data transmission signals, which allow the amplification gain to be regulated much more precisely than in the prior art.

This problem is solved by the independent claims.

The inventor has recognized that a major problem with the optical power amplification of data transmission signals lies in the fact that neither the actually coupled power of the pump laser nor the actual power consumption for regulating the power of the pump lasers used for amplification Strengthening or the profit - which would be even better - is measured, but only the performance of the pump laser. This ge ^¬ schieht generally characterized in that a part of the pumping laser light is cleaved prior to the coupling into the fiber, and measured by egg ne photodiode. There is a non-linear relationship between the measurement signal and the pump power actually coupled into the fiber, which is caused by further disturbance variables such as e.g. B. the temperature depends. This relationship can also be changed by aging effects. Furthermore, the gain achieved for a given pump power also depends on the power of the signals and their wavelength. Therefore, with the aid of the measurement signal obtained, the power coupled into the doped fiber can only be determined inaccurately.

A remedy can be provided in that the power control of the pump laser no longer measures the, actually uninteresting, power of the pump laser light itself, but rather determines the actual amplification power and controls its power based on the actual amplification power of the pump laser. As a result, the control is impaired by interfering influences, e.g. Temperature changes or aging avoided.

In so-called pumped optical power amplifiers, the physical property of doped optical waveguides is used, that electrons, excited by the light of the pump laser, are raised to higher energy levels, from where they, backed up by the light used for data transmission, fall back to their original energy levels give off their energy and in this way amplify the data-transmitting light. However, the electrons, which have been raised to higher energy levels, also have the option of accidentally falling back to the original level with a certain time constant or with a certain probability and thereby emitting a noise signal. This process is known as amplified spontaneous emission (= ASE). Typically, there are for this stochastically resulting signal is also not a preferred Ausbrei ^¬ tung directions, so that the ASE and progresses in both forward in the reverse direction the data transmission path. Since any light passing through it is amplified by the optical power amplifier, the amplified spontaneous emission (ASE) is also amplified accordingly and can therefore serve as a measure of the actual amplification of a light signal.

According to the invention, the actual amplification power is therefore measured on the basis of the intensity of the amplified spontaneous emission (ASE) and the power of the pump laser can be adjusted in such a way that the amplification of the data signals has a required value.

The ASE can be determined, for example, by the fact that it also propagates against the actual data transmission direction, or the intensity of the amplification can be measured at a wavelength that is free of data to be transmitted, so that here too pure ASE performance can be determined.

If, on the other hand, it is known which actual amplification power should reach a particular setting of a pump laser, this direct measurement of the amplification power via the ASE power can also be used to draw conclusions about aging processes or other errors occurring in the data transmission path.

It should also be mentioned that the method according to the invention can be used not only with fiber amplifiers but also with waveguide structures in the substrate and also with semiconductor amplifiers, the latter not being pumped electrically by light but by light. In accordance with this basic concept of the invention, the inventor proposes a method for controlling an optical amplification of a medium with a reinforcing effect in an optical data transmission system, to which energy is supplied by optical or electrical means and which one

Amplification of a light signal that passes through the medium, to improve in that the intensity of an amplified spontaneous emission is detected in the medium and, depending on this intensity, triggers a procedure which is related to the amplification power of the medium or the structure containing it becomes.

As mentioned above, the reinforcing medium can be, for example, an optical waveguide, a waveguide structure in the substrate or a semiconductor amplifier, the optical waveguide preferably being an optical fiber, and preferably the reinforcing medium with elements from the group of rare earths, is preferably doped with erbium.

According to an advantageous embodiment of the method according to the invention, it is proposed to couple forward-directed and / or backward-directed light in the detection of the amplified spontaneous emission (= amplified spontaneous emission = ASE), from which the gain can be determined quantitatively. The backward-directed light can be coupled out, for example, with the aid of a circulator or an isolator.

According to the invention, a frequency-dependent division of the forward and / or backward light into at least two frequency bands and measurement of the intensity in at least one frequency band, which is preferably free of data signals, can also be carried out when the amplified spontaneous emission (ASE) is detected become. For this purpose, the ASE suppression filter, which is often already built into optical amplifiers, lends itself to this to modify that the suppressed ASE can be detected with the help of a photodiode.

The energy can preferably be supplied optically by means of a pump laser light with a wavelength in the vicinity of 980 nm and / or 1480 nm.

The triggered procedure according to the inventive concept can be a control mechanism for the energy supplied, in particular for the power of a pumping laser, the proposed method being preferably used for the control of 980 nm lasers.

In a further preferred embodiment of the invention, the dependence on the actual amplification of a signal and the intensity of the amplified spontaneous emission (ASE) is first measured, for example in an experimental setup, and then this dependence is determined by a corresponding mathematical function or to determine the present amplification stored a table and used in determining the actual gain.

As already mentioned above, the triggered procedure can also be a monitoring mechanism for the functionality of an amplification device or an amplification path, with an alarm being triggered in the event of a change in the amplification power above and / or below a threshold value depending on the energy supplied and the signal power becomes.

Furthermore, according to the invention, the pump power emitted by individual pump lasers can be determined on the basis of the measured variables (signal powers and / or signal wavelengths and / or temperature) in order to detect changes in the performance data of the pump lasers. Likewise, based on the measured ASE power, the noise figure can amplifying means can be determined, wherein for loading ^¬ the noise figure humor their dependence on the amplified spontaneous emission (ASE) and optionally further influencing variables (for example the temperature) by one or more functions or tables is deposited.

According to the invention, the above-mentioned method can be carried out with a computer or microprocessor, a corresponding computer program with program means being used to carry out the steps, according to the previously described method, when the program is executed on a computer or microprocessor.

According to the invention, an optical isolator (= optical diode) can be used to detect the amplified spontaneous emission in a data transmission and / or amplification path with an input, an output and means arranged in between, which are suitable, among other things, for coupling out backward-directed light which has a means for detecting the backward light.

According to the invention, this optical isolator can be designed in such a way that the means arranged between the input and the output bring about an expansion of the light beam, light from the input to the output being focused on the output, while light running from the output to the input is not focused on the Input is focused.

Furthermore, the means arranged between the input and the output can contain two GRIN lenses with an intermediate arrangement of two polarizers and a Faraday rotator. In the following, the term polarizer means a component or a material in which the propagation properties of the light depend on the state of polarization. The means for detecting the backward light in the optical isolator according to the invention can be, for example, a photodiode.

According to the invention it is also proposed to improve an arrangement for the detection of an amplified spontaneous emission (ASE) in an optical data transmission and / or amplification path with an input and an output for light with optical data signals to be transmitted, in such a way that at least between the input and output a frequency divider and a detector are provided, at least one frequency range being coupled out without data signals and being fed to a detector.

In accordance with the method according to the invention described above, the inventor also proposes an optical data transmission path which contains the means for carrying out this method described.

Further features of the invention result from the claims and the following description of the exemplary embodiments with reference to the drawings.

The invention is described in more detail below with reference to the drawings:

Figure 1: Data transmission link;

FIG. 2: intensity curve of the light over the data transmission path; Figure 3: Optical isolator showing the light propagation in the signal direction; Figure 4: Optical isolator showing the light propagation against the signal direction; Figure 4a: Optical circulator; FIG. 5: decoupling of the non-signal-carrying light spectrum in the data transmission link; Figure 6: Representation of the functional context of ASE

Intensity of the amplification power actually transmitted to the signal; Figure 7: Schematic representation of a data transmission path with a multi-stage amplifier with a control of the pump laser power by measuring the backward ASE intensity.

FIG. 1 shows an optical data transmission link according to the invention from a transmitter 1 to a receiver 4 with the subsections 2.1 to 2.5 and power amplifiers 3.1 to 3.4 connected between them.

Correspondingly, FIG. 2 below shows a diagram of the intensity profile of the optical signal compared to the sections S1 to S5 indicated below with intermediate amplification sections VI to V4. It can be seen from the figure how the intensity of the data signal falls monotonously in the individual sections and is amplified again via the amplification section, in order then to fall again in the subsequent section of the transmission section until the signal finally reaches the transmitter from the receiver.

According to the invention, the amplification sections VI to V4 and the power amplifiers 3.1 to 3.4 can be, for example, an optical fiber doped with erbium, which is supplied with energy with the aid of a pump laser. On the input side, the power amplifiers 3.1 to 3.4 are each preceded by a detector according to the invention for measuring the amplified spontaneous emission 5.1 to 5.4 which propagates backwards. This can be, for example, an optical isolator known per se, in which a detector for measuring the backward light is additionally attached. Such an optical isolator according to the invention is shown in FIGS. 3 and 4, FIG. 3 using the arrows describing the forward direction of the light and FIG. 4 using the arrows describing the backward direction of the light passing through.

The optical isolators consist of an input 6 into which the light enters and an output 7 from which the light re-enters the data transmission path. There is a GRIN lens (GRIN = gradient index) on the input side and the output side. Between the two GRIN lenses is a Faraday rotator 9, which is formed by two magnets 11.1 and 11.2 and a normally non-optically active substance and is enclosed by a polarizer 10.1 and 10.2 on the input side and on the output side.

The arrows in FIG. 3 show how the incoming light is aligned on the input side to the first polarizer 10.1. The Faraday rotator 9 rotates the polarization by 45 ° around the two polarization axes. The light is then recombined in the GRIN lens on the output side and fed to the output 7.

As FIG. 4 shows, light entering against the data transmission direction and entering the optical isolator from the output 7 is likewise first directed to the second polarizer, passed through the two polarizers and the Faraday rotator between them, but in the GRIN lens on the input side, this backward light is no longer collimated onto the input side fiber, but spreads further divergent and in this way strikes the detector arranged on the input side, which encloses the incoming fiber here, and there the possibility of measuring the backward light and thus the increased spontaneous emission (ASE) opened. In addition to the situation shown of a directly attached detector, it is of course also possible to forward the backward light via an optical fiber to a remotely located detector.

Instead of an isolator, a circulator 35, as shown in FIG. 4a, can also be used. Light that is coupled in at gate A leaves the circulator 35 at gate B, while light coupled in at gate B leaves the circulator 35 at gate C. In the present application, the signals pass through the circulator 35 in the direction of data transmission from gate A to gate B, while at gate C the backward ASE can be detected, for example by a photodiode.

A circulator offers the same insertion loss for the paths from gate A to gate B and from gate B to gate C, which means that its structure is more complex than that of an isolator. As a result, the insertion loss is higher than with an isolator, which has a negative effect on the noise figure. An isolator should therefore be preferred.

Another arrangement for measuring the ASE is shown in FIG. Here, a filter 15 is interposed in the optical data transmission path, into which the entire spectrum 16 of the optical signal enters and is selectively split into two spectral ranges 16.1 and 16.2. The first, decoupled spectral range 16.1 is free of digital signals and thus only contains at least part of the noise of the entire signal. This portion of the

Spectrum 16.1 is then measured for its intensity using a detector 12 (here a photodiode). The non-decoupled sub-spectrum 16.2 of the data transmission signal is kept on the data transmission line and is directed towards the receiver. Since the spectral content is 16.1 zen of the data signal free of Frequen ^¬ over which the actual digital signal übertra ^¬ be gen, the intensity of this proportion is a measure of the amplified spontaneous emission (ASE) in the data transmission route.

Overall, FIGS. 3 and 4 thus show a device with which the backward ASE intensity can be measured in the data transmission link, while the device according to FIG. 5 opens up a possibility of measuring the ASE in the data transmission link that is in Direction of transmission of the data signal propagates.

To demonstrate that it is actually possible to draw a conclusion on the actual amplification of a reinforcing medium, in particular a sorted optical fiber or an optical substrate, on the basis of the measurement of the ASE intensity, FIG. 6 shows a diagram of the empirically measured relationship between the intensity of the measured ASE (X-axis) and the amplification of a continuous signal (Y-axis). Line 17 represents the intensity of the backward ASE as a function of the actually present gain in an erbium-doped optical fiber, while the line 18 below it shows the measured ASE intensity in the forward direction as a function of the actual gain, that is to say the actual gain of the data signals, in an erbium-doped optical fiber (EDFA).

Line 17 shows an almost linear course over one

Intensity range of almost 35 dB, while line 18 shows a slightly square functional relationship. Both lines increase in a strictly monotonous manner, so that a measurement of the value of the ASE intensity enables a clear conclusion to be drawn about the actual gain. The relationship between the measured ASE intensity and the present gain can be determined with the help be deposited by functions or table so that it is measured by the ASE intensity of the data transmitting light a direct conclusion about the effectiveness of the reinforcement ahead ^¬ possible.

On the basis of this relationship, the pump laser or an electrical energy supply to a medium with a reinforcing effect can be regulated in order to avoid that too little amplification power is used, which would result in an increase in the noise figure, or that one would increase large amplification power is caused, whereby non-linear effects in the fiber lead to strong signal distortions.

Finally, FIG. 7 schematically shows an optical data transmission link 2 with the internal structure of a multi-stage optical amplifier 32 with a first amplifier stage 33 (980nm) and a second amplifier stage 34 (1480nm). This example shows the combination of the proposed control method in the first amplifier stage 32 with the already known control method in the second amplifier stage 34. In the first stage 32 of the amplifier, a small part of the incoming signal from the data transmission path 2 is coupled out with a coupler 20 and to a signal power detector 21 to measure the strength of the incoming signal. The rest of the transmitted light is guided to an optical isolator 23 according to the invention, the structure of which is shown by way of example in FIGS. 3 and 4. Here, the backward ASE power generated in this stage is measured via the detector 12, followed by a further coupler 25 for coupling in the light from a pump laser with a wavelength of 980 nm. The pump laser 24 is controlled by the computer 22, wherein as the controlled variable, the measured backward ASE power verwen- det 24 is set and according to a stored function or a stored table in dependence of the ASE power, the ^'intensity of the pump laser so will result in an optimal amplification of the data signals in the first erbium-doped fiber (EDF) 26.

_A nschließend follows again an optical Isola- tor 23 with detector 12, for measuring the backward ASE to the EDF 26th Finally, the data signal is passed via a coupler 25, via which a pump laser with 1480 nm feeds the subsequent erbium-doped fiber 26. This is followed by an isolator 19 known in the prior art with a downstream decoupler 20, via which a partial signal is coupled out and in the signal output power detector 27 the intensity of the signal is measured at the end of the data transmission path. The information about this intensity is also fed to the computer, so that the pump laser 28 can be controlled. Alternatively, however, there is also the possibility of detecting the backward ASE power measured directly in front of the last coupler 25 and of using this information to control the pump laser 28.

The processor 22 is functionally divided into three task areas. The function block 30 has the task of regulating the pump power of the pump laser 24. To do this, the measured backward ASE is evaluated. This parameter also makes it possible to determine the noise figure for the first stage. Since the noise figure of the overall arrangement is largely determined by the first stage, that of the overall arrangement is also known.

The function block 29 serves to monitor the performance data of the pump laser 24. Based on measurements that were carried out at the time of commissioning, it is known how large the pump power or the current injected into the laser diode must be in order to achieve the gain determined from the measured backward ASE power at the measured input power. To improve the measurement, the input power can be measured spectrally resolved or the distribution of the input power from the measured services at the transmitters. If the pump power actually injected or the injection current actually supplied to the laser diode deviate from this value, the performance data of the pump laser 24 have changed. In this way, aging effects can be detected, for example.

The second amplifier stage can also be regulated in the same way. In the following, however, it will be described how the proposed control concept can be meaningfully combined with another control method. The aim of the amplifier control is to set a predetermined gain with the lowest possible noise figure. The already described regulation of the pump power of the pump laser 24 sets the optimal gain of the first amplifier stage and determines the noise figure of the overall arrangement. With the help of the function block 31, the pump power of the pump laser 28 is now set so that the desired gain of the overall arrangement results from the input 6 to the output 7.

In addition, it is pointed out that the term laser comprises all light sources which are suitable for making pump light available; in particular, this also includes laser diodes and semiconductor lasers. It should also be noted that the method according to the invention can be used both in one stage and in multiple stages in a data transmission link.

It goes without saying that the features of the invention mentioned above can be used not only in the respectively specified combination, but also in other combinations or on their own, without leaving the scope of the invention.

In summary, the invention therefore provides a method and a device for regulating the optical amplification of a medium with a reinforcing effect, in particular a doped optical fiber, the in- Intensity of the amplified spontaneous emission is used as a control variable for the amplification power, in particular the power of a pump laser, and amplification of digital signals in the saturation range is avoided. In this way it is achieved, in particular, that despite the amplification of a data transmission signal which is switched several times in succession, the maximum signal-to-noise ratio is achieved or only slightly undercut and noise of the transmitted data is prevented.

The English short names in the figures mean in detail:

Power performance

Power Detector

Wavelength wavelength

Signals signals

Erbium Doped Fiber Erbium doped fiber

Signal Input Power Signal input strength

Signal Output Power Signal output strength

Backward ASE backward ASE

Pump laser pump laser

Pump Power Monitoring l ^st stage 1st stage pump performance monitoring

Gain Control of l ^Ξt stage and Noise Figure Monitoring Gain control of the 1st stage and noise figure control

Overall Gain Control Overall gain control backward propagating backward spreading forward propagating forward spreading

Claims

claims

1. A method for controlling an optical amplification of a reinforcing medium (26) in an optical data transmission system to which energy is supplied by optical or electrical means and which causes an amplification of a light signal which passes through the medium, characterized in that the intensity of an amplified spontaneous emission (= amplified spontaneous emission = ASE) of the light in the medium (26) is detected and, depending on this intensity, a procedure which is related to the amplification power of the medium (26) or the structure containing it is triggered ,

Method according to the preceding claim 1, characterized in that an optical waveguide (26) or a semiconductor amplifier is used as the medium having a reinforcing effect.

Method according to the preceding claim 2, characterized in that the optical waveguide is an optical fiber (26) or a waveguide structure on a substrate.

Method according to one of the preceding claims 1 to 3, characterized in that the reinforcing medium (26) is doped with rare earths, preferably with erbium. , Method according to one of the preceding claims 1 to 4, characterized in that in the detection of the amplified spontaneous emission (= amplified spontaneous emission = ASE), forward and / or backward light is coupled out. A method according to one of the preceding claims 1 to 5, characterized in that the rearwardly directed light ge ^¬ with the aid of a circulator (35) or an insulator (23) is coupled.

Method according to one of the preceding claims 1 to 4, characterized in that upon detection of the amplified spontaneous emission (= amplified spontaneous emission = ASE) a frequency-dependent division of the forward and / or backward light into at least two frequency bands (14.1, 14.2) and The intensity is measured in at least one frequency band (14.1), which is preferably free of data signals.

Method according to one of the preceding claims 1 to

7, characterized in that pumping laser light is used at a wavelength in the vicinity of 980nm and / or 1480nm to supply energy.

Method according to one of the preceding claims 1 to

8, characterized in that the triggered procedure is a control mechanism for the energy supplied.

Method according to one of the preceding claims 1 to

9, characterized in that the triggered procedure is a control mechanism for the power of a pumping laser, preferably a 980nm laser (24).

Method according to one of the preceding claims 1 to

10, characterized in that to determine the present gain, the dependence on the actual gain and intensity of the ASE is stored and used by a function or a table. ^'

12. The method according to any one of the preceding claims 1 to

11, characterized in that the triggered procedure is a monitoring mechanism for the functionality of an amplification device or an amplification section.

13. The method according to any one of the preceding claims 1 to

12, characterized in that in the event of a change in the amplification power above and / or below a threshold value as a function of the energy supplied and the signal power, an alarm is triggered.

14. The method according to any one of the preceding claims 1 to

13, characterized in that the pump power output by individual pump lasers is determined on the basis of the measured variables in order to detect changes in the performance data of the pump lasers.

15. The method according to any one of the preceding claims 1 to

14, characterized in that the measured quantities are used to determine the noise figure of an amplifier (32).

16. The method according to the preceding claim 15, characterized in that for determining the noise figure, its dependence on the ASE and other influencing variables such as the signal power is stored by one or more functions and / or tables. 7. Computer program with program code means to carry out all steps according to one of the preceding claims 1 to 16 when the program is executed on a computer (22) or microprocessor.

18. Computer program with program code means according to the pressure upstream ^¬ claim 17, stored on a computer readable medium.

19. Transmission of a computer program according to the preceding claim 17 at least partially electronically between a transmitter (1) and a receiver (4).

20. Use of a computer program according to the preceding claim 17.

21. Optical isolator (= optical diode) for the detection of an ASE in a data transmission and / or amplification path with an input (6), an output (7) and means (8.1, 8.2) arranged in between, which are suitable for this purpose, among other things are to couple out backward light, characterized in that a means for detecting the backward light is provided.

22. Optical isolator according to the preceding claim 21, characterized in that the means (8.1, 8.2) arranged between the input (6) and the output (7) cause an expansion of the light beam, running from the input (6) to the output (7) Light is focused on the output (7), while light running from the output (7) to the input (6) is not focused on the input (6). 3. Optical isolator according to the preceding claim 22, characterized in that the means arranged between input (6) and output (7) means two GRIN lenses (8.1, 8.2) with an intermediate arrangement of two polarizers (10.1, 10.2) and a Faraday rotator (9) included. Optical isolator according to one of the preceding claims 21 to 23, characterized in that the means (12) for detecting the backward light is a photodiode.

Arrangement for the detection of an ASE in an optical data transmission and / or amplification path with an input (6) and an output (7) for light with optical data signals to be transmitted, characterized in that between the input (6) and the output

(7) at least one frequency divider (15) and a detector (12) are provided, at least one frequency range being coupled out without data signals and being fed to the detector (12).

Optical data transmission system between a receiver (4) and a transmitter (1) with a means for regulating an optical amplification of a medium (26) with a reinforcing effect, energy and the reinforcing medium (26) being supplied optically or electrically causes an amplification of a light signal which passes through the medium, characterized in that means are provided for measuring the intensity of an amplified spontaneous emission (= amplified spontaneous emission = ASE) in the medium (26), and means are provided which are provided in Depending on the intensity of the ASE, trigger a procedure which is related to the amplification performance of the medium (26) or the structure containing it.

Optical data transmission system according to the preceding claim 26, characterized in that the medium having a reinforcing effect is an optical waveguide (26) or a semiconductor amplifier.

28. Optical data transmission system according to the preceding claim 27, characterized in that the optical waveguide is an optical fiber (26) or a waveguide structure on a substrate.

29. Optical data transmission system according to one of the ^preceding claims 26 to 28, characterized in that the reinforcing medium (26) is doped with at least one element of the rare earths, preferably with erbium.

30. Optical data transmission system according to one of the preceding claims 26 to 29, characterized in that in the detection of the amplified spontaneous emission (= amplified spontaneous emission = ASE) forward and / or backward directed light is coupled out by a coupler.

31. Optical data transmission system according to one of the preceding claims 26 to 30, characterized in that a circulator or an isolator, preferably according to one of claims 21 to 24, is provided for coupling out the backward light.

32. Optical data transmission system according to one of the preceding claims 26 to 31, characterized in that in the detection of the amplified spontaneous emission (= amplified spontaneous emission = ASE) a frequency-dependent divider, preferably according to claim 25, for the forward and / or backward directed light in at least two frequency bands (14.1, 14.2) and a means for measuring the intensity in at least one frequency band (14.1), which is preferably free of data signals, are provided. _O ptisches data transmission system ^¬ one of the preceding claims 26 to 32, characterized in that superiors for supplying power pump laser with a wavelength near 980nm and / or 1480nm is seen / are in accordance.

Optical data transmission system according to one of the ^preceding claims 26 to 33, characterized in that the triggered procedure is a control mechanism for the energy supplied.

Optical data transmission system according to one of the preceding claims 26 to 34, characterized in that the triggered procedure is a control mechanism for the power of a pumping laser, preferably a 980nm laser (24).

Optical data transmission system according to one of the preceding claims 26 to 35, characterized in that to determine the present gain, the dependence on the actual gain and intensity of the ASE is stored in a function or a table in an electronic memory and with the aid of a microprocessor (22) is evaluated.

Optical data transmission system according to one of the preceding claims 26 to 36, characterized in that a monitoring mechanism, preferably in a microprocessor (22), is provided as the triggered procedure for the functionality of an amplification device or an amplification path.

The optical data communication system of one of the preceding claims 26 to 37, characterized marked is distinguished according to that a means, preferably a microprocessor (22) with an appropriate program is provided, ^'in the case that a change in the reinforce- power above and / or below a threshold value as a function of the energy supplied and the signal power triggers an alarm.

39. Optical data transmission system according to one of the preceding claims 26 to 38, characterized in that a means, preferably a microprocessor (22) with a corresponding program, is provided, which determines the pump power delivered by individual pump lasers on the basis of the measured variables Detect changes in the performance data of the pump laser.

40. Optical data transmission system according to one of the preceding claims 26 to 39, characterized in that a means, preferably a microprocessor (22) with a corresponding program, is provided which determines the noise figure of an amplifier (32) from the measured quantities.