EP1314267A1 - All-optical regenerator for wavelength-division multiplexed signals - Google Patents

Abstract

The invention concerns a regenerating device for wavelength-division multiplexed optical signals designed to simultaneously regenerate N channels of a multiplex. The invention is characterised in that at least one component of the regenerator (112, 152) is adapted to couple the input signal with a multiplex of N optical carriers, the regenerator component (112, 152) being made of a material having an inhomogeneous line broadening such that there should be no interaction between the various channels involved, within the component.

Description

 ALL-OPTICAL REGENERATOR FOR WAVELENGTH MULTIPLEX SIGNALS.

The present invention relates to the field of communications by optical fibers, and more precisely that of the regeneration of signals for such communications.

Those skilled in the art know that the online regeneration of signals propagating in fiber optic communication systems using wavelength division multiplexing (WDM) should make it possible to considerably increase the capacity of these systems. This subject is currently the subject of real enthusiasm on the part of equipment manufacturers and telecommunications operators.

There are 3 known types of signal regeneration:

A first type "1 R": the amplitude of the signal is simply amplified, without further processing. A second type "2R": the signal is amplified and reshaped (noise cancellation, partial or total restoration of the amplitude and / or spectrum) without resynchronization.

A third type "3R": in addition to the preceding operations, the temporal jitter of the pulses is suppressed (the signal is synchronous at the rhythm frequency).

Regeneration devices of the first type have the drawback of also amplifying the signal defects (noise, jitter, spectral distortion).

In what follows, we will only be interested in 2R or 3R type regeneration. There are two main approaches for the regeneration of optical signals: opto-electronic regeneration and "all-optical" regeneration.

In the first case, the signal is processed electronically after detection, and the regenerated electronic signal (noise-free, generally resynchronized) must then be transferred to an optical carrier, either by direct modulation of the current of a laser, or by l 'through an electro-optical modulator. This technique is very effective, but has the drawback of being particularly complex and expensive for very rapidly modulated signals (> 2.5 Gbit / s). In addition, the devices available today do not show any transparency at flow rate. In the second case, signal processing, including amplification, is obtained by purely optical means, thanks to various non-linear effects.

FIG. 1 symbolically represents the block diagram of a known all-type 2R optical regenerator. The optical input signal corresponding to data λ _D is amplified in an amplifier 10 and reshaped, without resynchronization: the power of the signal to be regenerated non-linearly modulates the power of a pure optical carrier (of wavelength λ _c , for example of a local laser) and non-noisy, using a component 12 whose transmission factor depends non-linearly on the incident optical power. The non-linear response of this gate 12 is adjusted so as to make it possible to reshape the signal and to eliminate part of the noise.

FIG. 2 schematically represents the principle of a known all-type 3R optical regenerator. In this case, as shown in FIG. 2, the signal leaving the regenerator is also resynchronized, that is to say that it is freed from the temporal fluctuations of the position of the pulses. This requires recovering the rhythm frequency of the incident signal (for example by processing in a module 14 the signal taken from the input using a coupler 16), from which a local optical clock is created which the 'we remodulate in the same way as in the case "2R" (modulation in a nonlinear optical gate 12 by the input signal amplified at 10). This more complex technique could be necessary if the time jitter of the signals becomes unacceptable, for example in the case of optical transmission systems with very high bit rates (beyond 10 Gbit / s) and long range (> 2000 km ). There are several types of regenerators proposed in the literature comprising an all-optical element acting under the effect of an optical signal such as an opto-optical gate, the transmission of which varies non-linearly as a function of the intensity of this signal. . A reference to the state of the art on the subject can be found in the reference [JC SIMON et al., "Ail Optical Régénération Techniques", ECOC'99, Nice, 26-30 September 1999]. To the knowledge of the inventors of the present invention, so far, for the regeneration of a set N of wavelength-division multiplex channels, it however proves essential to use as many opto-optical gates 12 with non-effect linear, as many channels of the wavelength multiplex, regardless of the effect used, in particular: - for opto-optical gates based on a saturated resonant interaction: i) cross absorption modulation (XAM in Anglo-American for "cross-absorption modulation"), or ii) crossed gain modulation (XGM in Anglo-American for "cross-gain modulation"), or iii) crossed phase modification (XPM in Anglo-American for "cross-phase modulation"), - for opto-optical doors based on a non-resonant interaction, such as the optical Kerr effect in an optical fiber made of silica glass (or other), cross-phase modulation.

The structure of a regenerator of the prior art can therefore be schematized by the figure 3-a: each channel of the multiplex is separated in a demultiplexer 20, then treated by a regeneration device per channel 12 _{1 f} ..., 12ι ... at 12 _n , then all the channels are re-multiplexed in a multiplexer 22.

The present invention now aims to provide a new optical signal regenerator device having higher performance than that of known prior devices.

This object is achieved in the context of the present invention by means of a device designed to simultaneously regenerate the N channels of a multiplex, characterized in that it comprises at least one regenerative component capable of coupling the input signal with a multiplex. N optical carriers, the regenerative component being formed of a material having a line with inhomogeneous widening so that there is no interaction between the various channels involved, within the component.

In the context of the present invention, the term “coupling” means the non-linear transfer of a signal over a multiplex. According to another advantageous characteristic of the present invention, the device designed to simultaneously regenerate the N channels of wavelength λ, of a multiplex, is characterized in that it comprises:

- a first regenerative component able to couple the input signal with a multiplex of N optical carriers of wavelengths λ ^' j, and - a second regenerative component able to couple the regenerated multiplex a first time on the comb of lengths d 'wave λ'j, at the output of the first component, simultaneously with a multiplex of N optical carriers, wedged on the comb of wavelengths λj in which the first and the second component are formed of a material having a widening line inhomogeneous so that there is no interaction between the various channels involved, within the components. According to another advantageous characteristic of the invention, a multi-wavelength filter calibrated on the multiplex λ'j is provided between the output of the first component and the input of the second component.

According to another advantageous characteristic of the invention, a multi-wavelength filter calibrated on the wavelengths λι is provided between the output of the second component. According to another advantageous characteristic of the invention, at least one of the multiplexes of N optical carriers is modulated by the rhythm frequency recovered from the corresponding channel.

Other characteristics, aims and advantages of the present invention will appear on reading the detailed description which follows and with reference to the appended drawings, given without limitation and in which:

- Figures 1 to 3 previously described schematically illustrate the state of the art,

FIG. 4 represents the general configuration of a regenerator in accordance with the present invention, and

- Figures 5 and 6 show two variants according to the present invention.

The principle of the regenerator in accordance with the present invention is based on the use of a single component performing the function of non-linear opto-optical gate regenerating all the N channels of the multiplex simultaneously.

The general block diagram of such a regenerator in accordance with the present invention is illustrated in FIG. 4.

The cases "2R" and "3R" will be described in more detail below. In the general case (illustrated in Figure 4), the N channels to be regenerated

(data Di), calibrated on the comb of wavelengths λj, are simultaneously coupled in a first regenerative component 112 with a multiplex of N optical carriers, of wavelengths λ'j or not modulated in the case "2R" , or modulated in the case "3R", each by the rhythm frequency recovered from the corresponding channel. Preferably, the input data are preferably amplified at 110, before being applied to the component 112.

At the output of the regenerative component 112, a multi-wavelength filter 130 (for example a Fabry-Perot standard or any other ad hoc filter) calibrated on the multiplex λ'j makes it possible to remove the incident data possibly transmitted at the output of the regenerative component 112.

In order to restore the data at the initial wavelengths and to perfect the regeneration, the previous operation is repeated by coupling, in a second regenerative component 152, the multiplex regenerated a first time on the comb of wavelengths λ'j, simultaneously with a multiplex of N optical carriers not modulated or modulated at the rhythm frequency of the corresponding channel, as in the previous case, and calibrated on the comb of wavelengths λj.

At the output of the second component 152, a filter 160 is placed calibrated on the wavelengths λj in order to recover only the regenerated data. Furthermore preferably, as seen in FIG. 4, the signal is amplified at 132 before being applied to the filter 130 and at 162 before being applied to the filter 160. In FIG. 4, 110, 132 and 162 represent optical amplifiers.

In the case where the regeneration level is not sufficient at the output of the filter 160, with the two regenerative blocks 1 12, 152 cascades as illustrated in FIG. 4, the configuration can be extended to X cascade regenerative blocks, with X> 2.

According to the invention, the non-modulated data and carriers are preferably transmitted in a co-propagative manner in the regenerative components 112 and 152.

The inventors have demonstrated that in this case, therefore involving two changes in wavelength (when it is desired to process signals without imposing any constraint on the polarization of the incident signal), the maximum bit rate of information processed is not limited only by the time of return to equilibrium of the non-linearity of the regenerative component.

However, as a variant, the input data signal and the multiplexes of N optical carriers can be transmitted counterpropagantly in the regenerative component 112 or 152.

In this case preferably a circulator is placed at the input of the regenerative component, on the side of the input of the data signal in order to allow the regenerated signal to be collected, and an isolator is placed at the output, in order to block the signal data. Furthermore, the wavelengths of the data signals and the corresponding wavelengths of the locally generated carrier multiplex can be identical. Each of the regenerative components 112 and 152 must, according to the invention, be formed from a material whose optical properties (absorption or amplification or refractive index or polarization, etc.) can be modified by an optical signal at a length of given wave, without this modification being able to affect another wavelength corresponding to an adjacent channel. Thus, according to the invention, the components 112 and 152 are formed by a material having a line with inhomogeneous widening, that is to say that the total line of fluorescence

(or absorption) consists of a set of finer homogeneous lines of width δλπ distributed within the inhomogeneous spectrum of width δλ | _NH , and not overlapping. In this way, the absorption, or gain, or phase modulation induced by a channel situated at a wavelength λj does not disturb the absorption, or the gain, or the phase of another channel at λj if the wavelength difference Δλ _c between these channels is greater than the homogeneous line width δλ _H of the material. There is therefore no interaction between the channels if the separation Δλ _c between the channels is greater than about δλμ. It is therefore possible according to the invention to process all of the N wavelength multiplex channels in the same component 112, 152; provided that N is less than or equal to the ratio δλi _NH δλH.

It is important that the separation between the wavelengths is not arbitrary. On the one hand, this separation must be much less than the homogeneous line width, so as to obtain an effective opto-optical modulation (therefore: δλ less than or equal to δλπ 4) and, on the other hand, that δλ is greater than the modulation bandwidth of the channel, in order to be able to efficiently filter the regenerated data (therefore δλ greater than or equal to 2δλ _inf0 ). In total, this limits the maximum bandwidth of the signal to be regenerated to around δλ _H 8.

In addition, it is necessary that the time of return to equilibrium of the non-linearity of absorption, or gain, or of refractive index of the components 112, 152, after disturbance by a signal pulse, is of the order of magnitude or a little shorter than the inverse of the frequency rhythm of the signal. Given the scope of applications targeted, this time is between 10 and 100 picoseconds.

This implies in particular that the homogeneous line width is equal to at least about twice the rhythm frequency of the data to be processed.

By way of example, the components 112, 152 can be formed from an absorbing semiconductor optical guide or amplifier, formed from quantum islands in the InAs system on an InP substrate [S. FRECHENGUES, Doctoral thesis, INSA Rennes, 27 Nov 1998], or even a glass guide including quantum islands of PbS [K. WUNDKE et al., Applied Physics Letters, vol. 76, N ° 1, 2000, pp. 10-12], these two materials being able to function at a wavelength of 1550 nm. In these two types of material, the inhomogeneous widening of the transition line comes from the variable size of the islands.

In the case where the separation between the channels is less than δλπ / 4 as specified above, it is difficult to correctly regenerate all of the channels with the structure described above and illustrated in FIG. 4, due to the crosstalk problems. It is then necessary to carry out a multiplication of multi-wavelength regenerators processing in parallel subsets of separate channels of approximately δλ _H as specified above. For that, as illustrated on figure 6, one can separate the data channels using a demultiplexer in wavelengths 100, then regroup the separated channels of a little more than δλ _H , using ad hoc multiplexers 102 ,, before coupling them into respective regenerative components 112j, with the comb of corresponding wavelengths generated locally. The outputs of the various components 112j are then grouped together in a multiplexer 104. FIG. 4 therefore represents the most general version of the multi-wavelength regenerator proposed in the context of the present invention based on two regenerative components.

However, as indicated, the device according to the present invention can comprise only one of such components.

The components 112, 152 formed from opto-optical gates based on non-linear material, can be the subject of numerous variant embodiments.

It may be an opto-optical door based on a material having either a saturable absorption or a saturable amplification, without modification of the refractive index.

Such a door can consist of two components separated by an optical isolator, a filter and an attenuator (if necessary). The signal to be regenerated is separated into two parts and coupled in parallel in each component, while the locally generated wave (continuous intensity or modulated by the recovered clock) crosses the two components in series. This configuration, which can be extended to K (K> 2) components if necessary, has the particularity of improving the extinction rate and reducing the amplitude noise on the regenerated data. On the other hand, it can reverse the polarity of the signal, in particular in the case where the opto-optical gates consist of optical semiconductor amplifiers, and therefore requires, in this case, a cascade of an even number of such gates to keep the polarity of the incident signal.

According to a variant, the data signal is coupled separately in the two regenerative components, while the locally generated carriers, modulated or unmodulated, successively pass through the two regenerative components.

It may be an opto-optical door based on material having a modulation of the refractive index induced by the data.

In this case, the opto-optical door can consist of a two-wave or multiple-wave interferometer, preferably a traveling wave such as a two-arm Mach-Zehnder interferometer, comprising in each arm a multi-length regenerative component of wave whose refraction has a spectrally inhomogeneous character in the sense described above.

It is also possible to use doors of different types in the same device. In the case of a "2R" regenerator, the configuration in accordance with the present invention is in accordance with what has been described in the general case of FIG. 4. The multiplexes of N optical carriers, of wavelengths λ, or λ'j, corresponding to a "multi-wavelength source" can be obtained by a set of non-modulated sources, produced by ad hoc means, and coupled in the regenerative components 112 or 152 by ad hoc means (N to 1 couplers or wavelength multiplexer for example).

In the case of a "3R" regenerator, the circuit preferably has the configuration illustrated in FIG. 5.

A small part of the input channel multiplex is taken with a coupler 140, then directed to a demultiplexer 142 in wavelengths. Each output of the demultiplexer 142 is separated into 2 channels by appropriate means, one directed to a clock recovery device 144 generating a source of short pulses synchronous with the frequency rhythm of the corresponding channel, at the wavelength λ'j, the other to an identical device 146 but emitting at length λj. Each output of the group of clocks at λ'j is recombined using appropriate means (a multiplexer 148 for example) inside the first multi-wavelength regenerative component 112, in which the main part of the data multiplex leaving the coupler 140 (after amplification at 110). The output of the multi-wavelength regenerative component 112 is filtered by appropriate means (130) to allow the regenerated data to pass through the comb λ'j (and possibly amplified at 132). These data are in turn coupled into the regenerative component 152 as well as the clocks set on the comb λj (grouped for example by a multiplexer 149). Finally, the regenerated data leaving 152, calibrated on the initial comb, are filtered at 160 to eliminate all traces of the data from 112 on the λV comb.

In a variant of this 3R regeneration device, the second comb of clocks with wavelengths λj can be simply replaced by a comb of carriers not modulated at λj, in particular when the second regenerative component consists of an opto door -interferometric optics operating in push-pull mode [K. TAJIMA JPn. J. Appl. Vol 32, Part 2, Nr 12A (1993) pp.L1746- 1749] Preferably, within the framework of the circuit illustrated in FIG. 5, delay lines are also provided (not shown in FIG. 5 to simplify the 'illustration) placed on the path of the clocks set on the comb λ'j and λj and chosen so that the information carried by the input signal arrives in synchronism with the information carried by these clocks, taking into account the delay introduced by the various elements which pass through these signals.

Various variants of the device in accordance with the present invention have been described above, comprising two regenerators 112, 152 cascaded: the first 112 operating an offset on the frequency of the carriers λ'j and the second 152 making it possible to restore the data at the initial wavelengths.

However, if necessary, the device according to the present invention may comprise a single regenerator operating on each given channel. The configuration illustrated in FIG. 6 is an example of such a variant allowing, thanks to a single multi-wavelength regenerative component 112 based on the saturated absorption in a material whose transition line is inhomogeneous widening as described more high, to improve the contrast (ratio between the power of the high level and that of the low level of an amplitude modulated binary digital communication signal) of each channel of the multiplex in wavelength. The entire multiplex is amplified using an optical amplifier 110 to bring the level of the multiplex to the value corresponding to the operating point of the non-linear component 112, then the multiplex is coupled in the multi-length regenerative component. wave 112. Due to the non-linear transmission, the lowest level is less transmitted than the highest level, which results in an improvement in contrast. One can of course cascade a second additional component (or even N components) if the contrast is not sufficient with a single component. However, the absorption recovery time must in this case be of the order of one tenth of the duration of the pulse to be regenerated, so as not to distort the signal too much. It should be noted that this device does not eliminate noise on the high level of the signal, unlike the devices described above.

It is understood that the present invention provides a device for "all-optical" regeneration of digitally modulated fiber optic telecommunication signals, making it possible to simultaneously process in the same component, N (N> 2) wavelength-division multiplex optical channels, with fewer regenerative components than what is required by state-of-the-art systems.

Of course, the present invention is not limited to the particular embodiment which has just been described, but extends to all variants in accordance with its spirit.

Claims

1. Regenerating device for wavelength multiplex optical signals designed to regenerate simultaneously the N channels of a multiplex, characterized in that it comprises at least one regenerating component (112, 152) capable of coupling the input signal with a multiplex of N optical carriers, the regenerative component (112, 152) being formed of a material having a line with inhomogeneous widening so that there is no interaction between the various channels involved, within the component

2. Device according to claim 1, characterized in that it comprises:

a first regenerative component (112) capable of coupling the input signal with a multiplex of N optical carriers of wavelengths λ'j, and

- a second regenerative component (152) capable of coupling the multiplex regenerated a first time on the comb of wavelengths λ'j, at the output of the first component (112), simultaneously with a multiplex of N optical carriers, wedged on the comb of wavelengths λj, in which the first and second components (112, 152) are formed from a material having a line with inhomogeneous widening so that there is no interaction between the various channels involved, within the components

(112, 152).

3. Device according to one of claims 1 or 2, characterized in that a multi-wavelength filter (160) is provided at the output of the regenerative component (112, 152) from which the output signal is taken.

4. Device according to claim 2, characterized in that a multi-wavelength filter (130) wedged on the multiplex λ'j is provided between the output of the first regenerative component (112) and the input of the second regenerative component (152).

5. Device according to one of claims 3 or 4, characterized in that the filter (130, 160) is formed of a Fabry-Pérot standard.

6. Device according to one of claims 1 to 5, characterized in that the multiplex applied to the regenerator (112, 152) is a locally generated signal without modulation.

7. Device according to claim 6, characterized in that the multiplex of N optical carriers applied to the regenerative component (112, 152) is generated by N sources coupled by an N to 1 coupler or a multiplexer, to the regenerative component (112, 152).

8. Device according to one of claims 1 to 5, characterized in that the multiplex of N optical carriers is modulated by the rhythm frequency of the corresponding input channel.

9. Device according to claim 8, characterized in that it comprises a coupler (140) capable of recovering part of the input signal and clock recovery means (144, 146) capable of respectively generating a source of synchronous pulses with the rhythm frequency of the channel corresponding to a wavelength λ'j and respectively pulses similar to the length

10. Device according to one of claims 8 or 9, characterized in that it further comprises delay lines placed on the path of the clocks and chosen so that the information carried by the input signal arrives in synchronism with the information carried by these clocks, taking into account the delay introduced by the various elements through which these signals pass.

11. Device according to one of claims 1 to 10, characterized in that it comprises an amplifier (110) upstream of the regenerative component (112, 152).

12. Device according to one of claims 1 to 11, characterized in that it comprises an amplifier (162) downstream of the regenerative component (112, 152).

13. Device according to one of claims 1 to 12 taken in combination with claim 2, characterized in that it comprises an amplifier (132) between the two regenerative components (112, 152).

14. Device according to one of claims 1 to 13, characterized in that the input data signal and the multiplexes of N optical carriers are transmitted co-propagatively in the regenerative component (112, 152).

15. Device according to one of claims 1 to 13, characterized in that the input data signal and the multiplexes of N optical carriers are transmitted counterpropagatively in the regenerative component (112, 152).

16. Device according to claim 15, characterized in that a circulator is placed at the input of the regenerative component, on the side of the input of the data signal in order to allow the regenerated signal to be collected, and that an isolator is placed at the output, in order to block the data signal.

17. Device according to one of claims 15 or 16, characterized in that the wavelengths of the data signals and the corresponding wavelengths of the locally generated carrier multiplex are identical.

18. Device according to one of claims 1 to 17, characterized in that it comprises a cascade X of regenerative blocks (112, 152) in series with X> 2.

19. Device according to one of claims 1 to 18, characterized in that the material making up each regenerator (112, 152) has a total line of fluorescence (or absorption) consisting of a set of finer homogeneous lines distributed within an inhomogeneous spectrum and not overlapping.

20. Device according to one of claims 1 to 19, characterized in that the difference in wavelengths δλ _c between two channels is greater than the width of homogeneous lines of the material making up each regenerator (112, 152).

21. Device according to one of claims 1 to 20, characterized in that the number N of channels is less than or equal to the ratio δλi _NH δλ _H , relationship in which δλi _NH represents the width of the inhomogeneous spectrum and δλ _H represents the width of the homogeneous lines.

22. Device according to one of claims 1 to 21, characterized in that the separation between the wavelengths λj-λ'i is less than the homogeneous line width.

23. Device according to claim 22, characterized in that the separation between the wavelengths λ - λ'j is less than or equal to δλ _H 4, δλ _H representing the width of a homogeneous line.

24. Device according to one of claims 1 to 23 characterized in that the separation between the wavelengths λj-λ'i is greater than the modulation bandwidth of the channel.

25. Device according to claim 24 characterized in that the separation between the wavelengths λj-λ'j is greater than twice the modulation bandwidth of the channel.

26. Device according to one of claims 1 to 25 characterized in that the time of return to equilibrium of the non-linearity of absorption, or gain, or refractive index, of the material making up the regenerator (112, 152), after disturbance by a signal pulse, is of the order of magnitude or even a little shorter than the inverse of the rhythm frequency of the input signal.

27. Device according to one of claims 1 to 26, characterized in that the homogeneous line width of the material constituting the regenerator (112, 152) is greater than or equal to twice the rate frequency of the data to be processed.

28. Device according to one of claims 1 to 27, characterized in that the regenerator (112, 152) is formed of an optical guide comprising quantum islands of variable size.

29. Device according to claim 28 characterized in that the regenerator (112, 152) is formed by an absorbing semiconductor optical guide or amplifier formed from quantum islands in the InAs system on the InP substrate.

30. Device according to claim 28, characterized in that the regenerator (112, 152) is formed by a glass guide including quantum islands of PbS.

31. Device according to one of claims 1 to 30, characterized in that it comprises means (100, 102) capable of grouping the channels separated by a distance greater than the width of homogeneous lines of the material constituting a component regenerator (112, 152) before applying these channels to a regenerative component (112, 152).

32. Device according to claim 31, characterized in that it comprises several regenerators (112j) working in parallel on groups of channels.

33. Device according to one of claims 31 or 32, characterized in that the means capable of grouping the channels are formed by a demultiplexer (100) and a multiplexer (102).

34. Device according to one of claims 1 to 33, characterized in that a regenerator (112, 152) is formed from an opto-optical door based on a material having either a saturable absorption or a saturable amplification, without changing the refractive index.

35. Device according to claim 34, characterized in that the regenerator (112, 152) is formed of two components separated by an optical isolator and a filter, see an attenuator.

36. Device according to claim 35, characterized in that the data signal is coupled separately in the two regenerative components, while the locally generated carriers, modulated or unmodulated, successively pass through the two regenerative components.

37. Device according to one of claims 1 to 36, characterized in that the regenerator (112, 152) is formed by an opto-optical door based on material having a modulation of the refractive index induced by the data.

38. Device according to claim 37, characterized in that the regenerator (112, 152) is formed by a two-wave or multiple-wave interferometer.

39. Device according to one of claims 1 to 38, characterized in that it comprises means (140) able to take a small part of the multiplex input channels, a demultiplexer (142) whose output is separated into two channels: one directed to a clock recovery device generating a source of short pulses synchronous with the frequency rhythm of the channel corresponding to the length wave λj, the other towards an identical device but emitting the wavelength λj, the two clock multiplexes thus obtained being coupled respectively in two regenerative components (112, 152), receiving in addition the first, the multiplex input data and the second, the output of the first regenerator.