WO2001035553A1

WO2001035553A1 - Channel synchronisation by dispersive fibre in a wavelength division multiplexing transmission system

Info

Publication number: WO2001035553A1
Application number: PCT/FR2000/003124
Authority: WO
Inventors: Emmanuel Desurvire; Bruno Dany; Olivier Leclerc
Original assignee: Alcatel
Priority date: 1999-11-10
Filing date: 2000-11-09
Publication date: 2001-05-17
Also published as: FR2800946B1; EP1145464A1; FR2800946A1; JP2003514433A

Abstract

The invention concerns wavelength division multiplexing transmission systems for regenerating channels by synchronous modulation in one point of the system where the channels are not synchronous. In order to achieve that, the regenerator has a dispersive optical fibre section and a synchronous modulator, the length and the dispersion of the section being selected so as to ensure synchronicity of the bit-times of the channels in the synchronous modulator input.

Description

DISPERSIVE FIBER CHANNEL SYNCHRONIZATION IN A WAVELENGTH MULTIPLEXED TRANSMISSION SYSTEM

The invention relates to optical fiber transmission systems with wavelength multiplexing, and more specifically, optical modulation in such transmission systems.

The transmission of soliton or soliton pulses is a known phenomenon. These pulses are RZ pulses of temporal width (FWHM, pulse width at half the maximum power) which are small compared to the bit time, which have a determined relationship between power, spectral width and temporal width, and which generally propagate in the so-called abnormal dispersion part of an optical fiber. The evolution of the envelope of such a soliton pulse in a single-mode fiber can be modeled by the nonlinear Schrodinger equation; propagation is based on a balance between the abnormal dispersion of the fiber and its non-linearity. To control the jitter of such soliton signals, various solutions have been proposed. It is known to use sliding guiding filter systems, see for example EP-A-0 576 208. It has also been proposed to carry out synchronous modulation of the soliton signals. Modulators of different types can be used for this, and in particular synchronous amplitude or phase modulators using the err effect. In H. ubota and M. Nakazawa, Soliton Transmission Control in Time and Frequency Domains, IEEE Journal of Quantum Electronics, vol. 29 no.3, 21 89 or in NJ Smith and NJ Doran, Evaluating the Capacity of Phase Modulator-Controlled Long-Haul Soliton Transmission, Optical Fibers Technology I, 21 8-235 (1 995) a review of the various control techniques or of regeneration of soliton signals. K. Suzuki et al., 40 Gbit / s single channel optical soliton transmission over 70,000 km using in-line synchronous modulation and optical filtering, Electronics Letters, vol. 34 no. 1 (1 998), pp. 98-100 is an experimental demonstration that close filtering, combined with intensity and phase modulation, allows single-channel transmission over large distances. The type of propagation proposed in this document for soliton signals is not directly applicable to systems with wavelength multiplexing, due to the effects of collisions between solitons of the different channels. NJ Smith et al., Enhanced power solitons in optical fibers with periodic dispersion management, Electronics Letter, vol. 32 no 1, pp. 54-55 (1996), describes a modified propagation scheme of soliton signals, to overcome this limitation; we alternate sections of fiber with positive and negative dispersion so that we have a low average dispersion (little jitter) with a significant local dispersion and therefore reduced WDM effects (the channels slide quickly relative to each other) . This dispersion-managed soliton propagation scheme makes possible wavelength-division multiplex transmission systems.

It has been proposed in wavelength division multiplex fiber optic transmission systems to regularly use synchronous modulation of the signals; such modulation is preferably optical, especially for high speed systems. The problem then arises of the differences in group speeds between the channels, due to the differences between the wavelengths. Various solutions to this problem have been proposed. An article by

E.Desurvire, O. Leclerc and O. Audouin, Synchronous in-line regeneration of wavelength-division multiplexed solitons signais in optical fibers, Optics Letters, vol. 21, n ° 14, pages 1026-1028 describes a wavelength allocation scheme which is compatible with the use of synchronous modulators for soliton signals. This article proposes to allocate wavelengths to the different channels of the multiplex so that, for given ZR intervals between the repeaters, the signals of the different channels, or more exactly the bit times of the different channels of the multiplex, are substantially synchronized. arriving at the repeaters. This allows online synchronous modulation of all channels, at given intervals, using discrete synchronous modulators. This multiplex wavelength allocation technique is also described in French patent application FR-A-2,743,964 in the name of Alcatel Submarine Networks. In this article, it is proposed to choose a subgroup of channels, synchronous not only at ZR intervals, but also at intervals under multiples of ZR. O. Leclerc, E. Desurvire and O. Audouin, Synchronous WDM soliton regeneration: towards 80-160 Gbit / s transoceanic Systems, Optical Fiber Technology, 3 pages 97-1 16 (1997) specifies that this scheme for the allocation of lengths d can lead to too large ZR intervals between the synchronous modulators, or at too great spacing between the channels of the multiplex. To overcome this problem, this article notes that in such a wavelength allocation scheme, the bit times of channel subsets of the multiplex are synchronous at sub-multiple intervals of ZR. The article consequently proposes to regenerate, at lower intervals, subsets of channels of the multiplex. However, this solution requires filtering of the channels of the subset to be regenerated, and makes the transmission system lose the single periodicity for all the channels.

FR-A-2 770 001 proposes to use a synchronous modulator to modulate the soliton signals of all the channels of a transmission system with multiplexing in wavelength at a frequency N / T multiple of the clock frequency of the 1 / T signals. In this way, we can relax the synchronicity constraint, by imposing no longer a bit time synchronicity, but a synchronicity of the different channels at a sub-multiple of the bit time. FR-A-2 759 516 proposes to demultiplex the different channels, and to apply to them the delays necessary to resynchronize them. After multiplexing, the different channels can be modulated using a single optical modulator. The French patent application filed under the number 97 06 590 proposes using a chain of networks formed in a fiber to apply suitable delays, and thus resynchronize the different channels without having to demultiplex and remultiplex.

In the case of non-soliton RZ signals, FR-A-2 759 830 proposes a synchronous modulation technique by converting the non-soliton signals into soliton signals via a fiber section preceded by an amplifier delivering the power necessary for the conversion of the pulse into a standard soliton of

Schroding, then by synchronous optical modulation of the signals, in phase or in intensity. The soliton signals are then re-injected into the line, thus carrying out a reverse conversion into non-soliton RZ signals. In this document, a passage through a highly dispersive optical fiber with a suitable input power corresponding to the soliton power is used for the conversion. P. Brindel et al., "Black-box" optical regenerator for RZ transmission Systems, Electronics Letters, vol. 35 no. 6 (1999), pp. 480-481 shows that the optical regeneration of signals in such a device is more efficient when the phase and intensity modulations are separated, the phase modulation taking place before the conversion fiber, and the intensity modulation taking place at the output of the conversion fiber. B. Dany et al., Transoceanic 4x40 Gbit / s System combining dispersion-managed soliton transmission and new "black-box" in-line optical regeneration, Electronics Letters, vol. 35 no. 5 (1,999), pp. 418-420 applies this regeneration technique to a four-channel transmission system using soliton propagation with dispersion management, with channel separation and one regenerator per channel.

The invention proposes a solution to the problem of the synchronicity of the channels of transmission systems with wavelength multiplexing, and makes it possible to implement synchronous modulation of the channels. It also provides a solution to the problem of channel synchronization both for phase modulation and for amplitude modulation, in a regeneration device of the type of FR-A-2 759 830.

More specifically, the invention proposes a regenerator for receiving and regenerating a plurality of wavelength and asynchronous multiplex channels at the input of the regenerator, comprising a section of dispersive optical fiber and a synchronous modulator, the length and the dispersion of the said section being chosen so as to ensure the synchronization of the bit times of the channels at the input of the synchronous modulator. In one embodiment, the regenerator further comprises a second section of dispersive optical fiber at the output of the modulator.

Advantageously, the product of the length by the chromatic dispersion for the said second section of optical fiber is the opposite of the product of the length by the chromatic dispersion for the said section of optical fiber. Preferably, the dispersive optical fiber has a negative dispersion.

The invention also provides a wavelength division multiplex transmission system, comprising at least one such regenerator at a position in the system where the channels are asynchronous. In this case, it is preferable that the section has a dispersion of sign opposite to the average dispersion in the line fiber of the transmission system.

The invention also proposes a regenerator comprising a first synchronous modulator, a section of conversion fiber and a second synchronous modulator, the length and the dispersion of said section being chosen so as to ensuring the synchronization of the bit times of the channels at the input of the second synchronous modulator.

Preferably, the first modulator is a phase modulator, and the second modulator is an intensity modulator. One can also provide an amplifier between the first modulator and the converting fiber section and choose the chromatic dispersion of the converting fiber so that the peak power of the signals in the converting fiber is less than or equal to the output power of the amplifier.

Advantageously, the signals in the converting fiber section are soliton signals, and the length of the converting fiber section is a multiple of the period of the soliton signals.

In another embodiment, the first and the second modulator have a common clock recovery device.

The invention finally proposes a transmission system with wavelength multiplexing, comprising at least one such regenerator.

Other characteristics and advantages of the invention will appear on reading the following description of embodiments of the invention, given by way of example and with reference to the appended drawings, which show FIG. 1, a schematic representation of dispersion in a transmission system implementing the invention; Figure 2, a schematic representation of the dispersion in another transmission system implementing the invention; FIG. 3, a representation of the quality factor in a transmission system of the prior art; - Figure 4, a representation of the quality factor in a transmission system according to the invention; Figure 5, a schematic representation of a regenerator according to another embodiment of the invention; FIG. 6, a representation of the quality factor in a transmission system using regenerators of the type of that of FIG. 5; FIG. 7, a representation of the quality factor, in a system in which the channels are regenerated separately. The invention proposes, in order to allow synchronous modulation of all the channels or of a part of these in a transmission system with wavelength multiplexing, to synchronize the bit times of the different channels, by virtue of a section of dispersive fiber. The invention is described with reference to FIGS. 1 to 4 in the case of a transmission system where the dispersion slope (or third order dispersion) is canceled by means of reverse dispersion fiber (in English, "Reverse Dispersion Fiber ", or RDF).

The invention also applies to regenerators using a conversion fiber. In such a case, as explained with reference to FIGS. 5 to 7, an appropriate choice of the dispersion of the conversion fiber makes it possible to ensure the synchronicity of the bit times of the different channels, not only for phase modulation, but also for amplitude modulation.

It allows passive and simultaneous channel synchronization, without requiring demultiplexing of the channels. It makes it possible to remove the constraint imposed in the prior art by the relationship between the wavelengths of the channels and the periodicity of the synchronous modulation; it becomes possible, as explained in the examples which follow, to freely choose the position of the modulators, independently of the relationships between the wavelengths of the channels.

Figure 1 shows a schematic representation of the dispersion in a transmission system implementing the invention. As indicated above, the system considered as an example for the explanation of the invention uses a fiber with inverse dispersion for the compensation of the dispersion slope. Provisions are made, at intervals Z _R along the system, for regeneration by synchronous modulation of all the channels or of only part of the channels. As explained above, the problem in this case is to ensure the synchronicity of the channels to allow modulation.

The distance along the transmission system, denoted z, is shown on the abscissa in FIG. 1. The chromatic dispersion D (z), which is a function of distance, is plotted on the ordinate. As shown in the figure, between the abscissae 0 and Z _R , the transmission system is made up of different alternating segments of fiber of positive and negative dispersion. We can for example use for the odd order segments in the figure a shifted dispersion filbre ("DSF" or "Dispersion Shifted Fiber" in English), having a positive dispersion and a slope of positive dispersion. To compensate for the dispersion slope, the odd-order segments are formed of a fiber having a negative dispersion, and a negative dispersion slope. The relative length of the even and odd order segments is chosen so as to cancel the cumulative dispersion slope over the wavelength range of the multiplex, which can be written L _P. (DD / dz) _P = - L,. (DD / dz) ,, the letters "P" and "I" indicating the even and odd order segments respectively. Under these conditions, after a transmission length Z _R , a substantially zero cumulative dispersion slope is obtained, and a dispersion equal on average to the value D _m or D plotted in FIG. 1. In this hypothesis, after propagation over a distance z, a channel of order k, separated from k.Δλ of a channel of order 0, undergoes with respect to the channel of order 0 a time shift T _k0 , which s 'writes: T ₀ = T _k - T ₀ = k.Δλ.D _m .z The invention proposes to compensate for this offset to ensure synchronicity of the bit times and allow synchronous modulation of the channels. To this end, it proposes to insert before the modulator a fiber section, called compensation fiber. The length Z _comp and the dispersion D _comp of this compensation fiber are chosen so as to ensure the synchronicity of the bit times of the different channels at the input of the modulator. From this point of view, it will be noted that it is not necessary to allow synchronous modulation to compensate for the whole of the time offset between the channels, but that it suffices to compensate for the fractional part of the offset expressed as a multiple of time. bit; in other words, the length and the dispersion of the compensation fiber can be chosen so that the slip between the channels is an integer multiple of the bit time T _bit . Here we call bit time as is conventional in transmission systems the period of each piece of information.

In the embodiment of FIG. 1, a synchronous modulator, which modulates the channels, or part of the channels, has been inserted after the compensation fiber section. This modulator can be an intensity or phase modulator. A second fiber section is further provided after the modulator, making it possible to cancel the effects of the compensating fiber section on the chromatic dispersion; one can typically use a fiber having a dispersion -D _{œmp /} and a length Z _comp . The insertion of such a second section of fiber makes it possible not to modify the chromatic dispersion in the transmission system, and is particularly advantageous in the case of transmission systems using soliton pulses; in fact, as explained above, the propagation of the soliton pulses also results from a control of the dispersion. One could also, as in the embodiment of FIG. 2, described below, not use such a second fiber section after the modulator.

We denote by Z _s below the length over which two neighboring channels are offset by the bit time T _bit . This length is written:

Z _s = T _bi J (D _m .Δλ) Using this notation, the offset T _k0 between the channels of order k and of order 0 is written

T _k0 = kT _bit z / Z _s

It is sufficient to allow synchronous modulation at a distance z to compensate for the time offset which corresponds to the fractional part of the offset expressed in multiples of the bit time; between the channels of order k and 0, it suffices to compensate for the offset t _k o ⁼ T o - T _bi) .E (T _k0 / T _bit ) where E (x) is the well-known function which has a number x associates its entire part. This offset can be compensated for by inserting into the transmission system a section of optical fiber having a dispersion D _comp and a length Z _comp . In this case, the offset induced between two channels in the compensating optical fiber section is written by analogy with the preceding formula: ho ⁼ Δλ, U _∞rnp -. _comp

Synchronous modulation is possible if this offset induced in the compensation fiber restores the synchronicity of the bit times of the different channels. The characteristics of the section of the compensating fiber depend on the position in which this fiber is arranged.

Thus, it is clear that at multiple distances from the distance Z _s defined above, the bit times of the different channels are synchronous, and that it is not necessary to provide a compensation fiber section.

For a system of the type of that of FIG. 1, in which the modulator is followed by a second fiber section. It is also clear that the time lags between the different channels have a spatial periodicity of Z _s , so that it suffices to consider the case of modulators placed between z = 0 and z = Z _s .

A sufficient condition for the bit times to be synchronous after propagation over a distance Z in the transmission system and over a distance Z _comp in the compensation fiber section is that the propagation in the compensation fiber section compensates for the time difference between two neighboring channels, that is to say:

I _b i _t Z / Zs = -ΔλD _comp Z _comp with Z <Z _s , or for Z> Z _s , T _bit (Z / Z _s - E (Z / Z _S )) = -Δλ D _comp Z _comp for Z> Z _s . These two formulas lead to identical results in view of the periodicity of the offset between channels in a transmission system with zero dispersion slope on average, with a second fiber section after each modulator. As an example, we can consider a spacing between channels Δλ of 0.5 nm and a bit time T _bit of 100 ps corresponding to a bit rate of 100 Gbit / s. For a system with an average dispersion D _m of 0.5 ps / (nm.km), we find a value of Z _s of 400 km. To be able to place regenerators by synchronous modulation every 100 km, it suffices to compensate after propagation of 100 km an offset of a quarter of the bit time, after 200 km an offset of half the bit time, and after 300 km an offset three-quarters of the bit time. After 400 km of propagation, the bit times are synchronous. The system is periodic with a period of 400 km. To compensate for the offset after 100 km of propagation, a fiber with a length Z _comp of 1 km can be used, in which case a D _Dmp value of -100 ps / (nm.km) is obtained, which is achievable in the practice. We can then after 200 and 300 km of propagation use the same fiber, but with respective lengths of 2 and 3 km. For signals at 40 Gbit / s, i.e. T _bit = 25 ps, after 100 km of propagation a D _comp value of -1 2.5 ps / (nm.km) is obtained, which is achievable with current RDF fibers . We can in this case use after 200 or 300 km of propagation an identical fiber, in a longer length Z _comp , or even use an identical fiber length, with higher values of chromatic dispersion.

FIG. 2 shows a schematic representation of the dispersion in another transmission system implementing the invention; the system of figure 2 is identical to that of FIG. 1, except that a second fiber section is not provided after a synchronous modulator making it possible to restore the initial value of the chromatic dispersion. In other words, in the embodiment of FIG. 1, the insertion of a modulator and of the two corresponding fiber sections is transparent from the point of view of the cumulative chromatic dispersion in the transmission system; on the contrary, in the embodiment of FIG. 2, the insertion of a modulator induces a disturbance in the cumulative chromatic dispersion.

As shown in Figure 2, it is advantageous in this case to provide that the compensation fiber is distributed, and is on the one hand before the modulator, and on the other hand after the previous modulator, or at the start of the section previous line fiber. This separation of the compensation fiber makes it possible, in a soliton propagation mode, to limit the disturbances brought to the solitons, due to the propagation in a fiber section whose dispersion is not adapted to soliton propagation. In the embodiment of FIG. 2, the bit times are synchronous at the output of each modulator, and the chromatic dispersion accumulated along the transmission system is partially compensated for by the compensation fibers. In other words, we go from an average dispersion D _m to an average dispersion D _m + D _comp / Z _R , with Z _R the distance between two modulators. The embodiment of FIG. 2 also has the advantage of limiting the length of the compensation fiber. As an example, we can use the numerical values proposed above. To insert a modulator every 100 km, one can use at each modulator a section of fiber to compensate for a dispersion D _comp of -100 ps / (nm.km) for a bit time of 100 ps, a spacing between channels Δλ 0.5 nm, and a length Z _comp of one kilometer. After each modulator, the bit times of the different channels are synchronous, and it suffices to compensate the modulator according to the time offset induced from the following modulator, and not as in the embodiment of FIG. 1, the time offset induced from the start of the transmission system. In other words, in the numerical example, one can use every 100 km a fiber section with a length Z _comp of 1 km, with a dispersion D _œmp of -100 ps / (nm.km); in the embodiment of FIG. 2, a section of length Z _comp / 2 is used before a modulator, and a section of length Z _comp / 2 after the modulator. If we consider a fiber length of 1.5 km before and after each modulator, it is possible with the same numerical values to use a dispersion fiber D _comp of -16.6 ps / (nm.km); such a fiber has a dispersion close to the dispersion of an RDF SMF compensation fiber. With the example of a transmission at 40 Gbit / s, one can insert before and after each modulator a length Z _œmp / 2 of 0.5 km of fiber with a chromatic dispersion D _comp of -25 ps / (nm. km).

FIG. 3 shows for comparison a representation of the quality factor as a function of the distance in a soliton signal transmission system of the prior art, while FIG. 4 shows a representation of the quality factor in a transmission system according to the invention. The representation in FIG. 1 corresponds to a system with 4 channels of 40 Gbit / s each, in which the wavelengths of the channels are chosen so as to ensure natural synchronicity with a period Z _s of 150 km. Optical modulators are available with a Z _R periodicity of 150 km. The quality factor tends asymptotically towards a minimum value of 9, for a distance of 6,000 km. FIG. 4 corresponds, for this same system, to a periodicity of the modulators Z _R of 180 km, ie a shift of the order of 20% of the bit time. To compensate for the delay between channels, a fiber having a dispersion Z _comp of -1 7 ps / (nm.km) is used; the length Z _comp is _equal to 600 m. With a system of the type of that of FIG. 2, in which the dispersion induced by the compensation fiber is not canceled, a fiber section of length Z _comp / 2 of 300 m can be provided before and after each modulator.

It can be seen in FIG. 4 that first of all the insertion of compensation fiber to synchronize the channels has only a marginal effect on the quality factor, which remains equivalent to that of FIG. 3. The embodiment of FIG. 2 is therefore viable not only for RZ signals, but also for soliton signals for which the dispersion is managed in the transmission system; finally, this solution remains valid for conventional soliton pulses, that is to say without management of the dispersion in the transmission system. In the above examples, we have considered for simplicity the case of a system in which the dispersion slope is zero; the invention applies in the same way to the case of a system in which the dispersion slope has a non-zero mean value D '_m; in this case it suffices to choose for synchronization channels a compensation fiber with a dispersion slope D ' _comp which checks:

* - 'comp * ^ - comp ^ rrr ^ - for a modulator placed at a distance Z less than or equal to Z _s . For Z> Z _s , we obtain a system of 2 equations to solve:

T _bit (Z / Z _s - E (Z / Z _S )) = -Δλ D _comp Z _∞mp (1)

The first equation is the same as in the previous case, and corresponds to the compensation of the fractional part of the shift between the bit times, generated by the dispersion. The second equation represents the additional offset introduced by the slope of the dispersion; this additional offset is generally small compared to the offset induced by the dispersion.

The invention can be applied even if the synchronization between the channels is not perfect; it also applies with the formulas proposed above, even if the chromatic dispersion slope is not perfectly zero. A synchronization fault between the channels of the order of ± 5% of the bit time is acceptable, and allows synchronous modulation.

Figure 5 shows a schematic representation of a regenerator according to another embodiment of the invention; the regenerator of FIG. 5 is a regenerator of the kind described in the article by P. Brindel mentioned above. The regenerator has at its input a coupler 4 to take part of the signal which is sent to a clock recovery device 6. Downstream of the coupler is provided a phase modulator 8, which receives a clock signal from the device clock recovery 6. At the output of the phase modulator, the modulated signals are amplified in an amplifier 10, then are injected into a conversion fiber 11 to transform the signals into soliton signals. As indicated in the aforementioned articles, or in the patent application, it is possible to use for the conversion fiber a fiber of a strictly positive dispersion typically between 2 and 1 7 ps / nm.km. After the dispersion fiber, a narrow filter 1 2 is provided, then a coupler 14 which takes part of the signal and sends it to a clock recovery device ό. The filtered signal is transmitted to an intensity modulator 18, which also receives the signal from the clock recovery device. Such a regenerator is proposed in the aforementioned articles for a single channel. The invention, as described with reference to FIGS. 1 to 4, makes it possible to use the regenerator for the synchronous regeneration of the signals originating from different channels of a transmission system with wavelength division multiplexing. The invention also proposes, in such a regenerator, to choose the characteristics of the conversion fiber, so as to ensure the synchronicity of the bit times of the different channels at the input of the intensity modulator. The invention also makes it possible to use only one clock recovery device, in particular in cases where the length of the conversion fiber is not too great, so that the clock signal for modulation intensity can be derived from the clock signal for phase modulation. If the length of the conversion fiber is too great, it may be useful to keep, as in the prior art, two clock recovery circuits, so as to be able to take account of possible phase drifts in the conversion fiber. Assuming that the bit times of the different channels are synchronous at the output of the amplifier, the length Z _∞mp and the dispersion D _comp of the conversion fiber are chosen so as to satisfy

Z _a.mp -D _comp = kT _bi JΔλ (1) with the same notations as above, and k an integer. This condition ensures that the offset between two channels in the conversion fiber is an integer multiple of the bit time. This condition applies if the chromatic dispersion slope of the conversion fiber is neglected.

If we take into account the chromatic dispersion slope of the conversion fiber, denoted D ' _comp , we have kT _bit = Z _∞mp .D' _comp .Δλ (Δλ + 2Δλ ₁₀ ) / 2 (2) with Δλ ₁₀ the spectral difference between the wavelength λ, of the channel at the lowest wavelength, and the wavelength λ ₀ where the dispersion of the fiber (or average dispersion of the section) is zero.

These relationships ensure the synchronicity of the bit times at the input of the intensity modulator. As in the previous embodiment, it is possible to admit synchronization faults between the channels of the order of 1 to 2% of the bit time. In addition, it is advantageous that the chromatic dispersion of the conversion fiber is as high as possible, so as to minimize the period Z ₀ of the "pseudo" soliton signals obtained at the output of the conversion fiber. This period Z _{0 is} written:

with Δt the time width of the RZ pulse at the input of the conversion fiber, and λ the wavelength of the channel (which one?). Minimizing the period Z ₀ improves the conversion for a given length of the conversion fiber. It is also advantageous, to favor the conversion, that the length Z _comp of the conversion fiber is a multiple of the period Z ₀ of the "pseudo" soliton signals.

Another possible constraint in the choice of the conversion fiber is the constraint on the peak power of the soliton pulses in the conversion fiber. This peak power is written: p _{c =} I -n ^! (| +. ^ / 2) _r * ³ . ^ eff _ D ^ ₍₄₎ πcu ₇ Δt with n ₂ and A _eff the non-linearity index and the effective area of the conversion fiber. It is preferable that the peak power of the solitons is chosen so as not to exceed the output power of the amplifier. A limit value of 20 dBm corresponds to an acceptable output power of the amplifier. Such a constraint limits the value of the chromatic dispersion of the conversion fiber. The choice of the chromatic dispersion of the conversion fiber is therefore made within the range defined by formulas (3) and (4). The length of this fiber and the chromatic dispersion in the range are chosen so as to ensure the synchronicity of the bit times for the intensity modulation, using formulas (1) and (2). The following table gives the quality factors Qa and Qt in amplitude and time in a regenerator of the type of FIG. 5, used for the synchronous regeneration of a multiplex at 4 x 40 Gbit / s. These quality factors are measured in a manner known per se. In the example, channels are used at wavelengths 1,548, 1,550, 1,552 and 1,554 nm, with RZ pulses of the raised sine type having a width at mid-height of 1 2.5 ps. The conversion fiber is an NZDSF fiber, with a length Z _comp of 2.53 km, and a chromatic dispersion of + 5ps / nm.km. The cross section of the fiber is 80 μm ² , and the non-linearity index is equal to 2.710 ^"20 m ² / W. Under these conditions, the period Z ₀ of the pseudo solitons is approximately 2.5 km; the fiber conversion therefore has a length at least 0.7 times this period.

The results in the table above show that the regenerator of the invention can be used for the synchronous regeneration of the channels of a wavelength multiplex.

FIG. 6 shows a representation of the quality factor in a transmission system using regenerators of the type of that of FIG. 5; the distance traveled in the transmission system is plotted on the abscissa, and the quality factor for each of the channels is plotted on the ordinate; this quality factor is the lower of the two factors Qa and Qt. The transmission system is a 4 x 40 Gbit / s system with the same wavelengths as those used to obtain the results in the table. The pulses are soliton pulses managed in dispersion. The system presents amplifiers with a periodicity of 40 km, and regenerators of the type of that of FIG. 5, with a periodicity of 240 km. It can be seen in the figure that the Q factor tends asymptotically towards values of 8 to 10 for distances of 8,000 km, which proves the efficiency of the regenerator of the invention.

By way of comparison, FIG. 7 shows a representation of the quality factor, in a system in which the channels are regenerated separately. The transmission system is similar to that of FIG. 6, but the channels are regenerated separately by regenerators of the type of the aforementioned article by P. Brindel and others, after demultiplexing. It can be seen that the quality factor, after 8,000 km of propagation, reaches values similar to those of FIG. 6. The invention thus allows synchronous regeneration of the different channels of the multiplex.

Of course, the present invention is not limited to the examples and embodiments described and shown, but it is susceptible of numerous variants accessible to those skilled in the art. In the examples, we have considered the simplest case where all the channels are synchronous, so as to allow synchronous modulation of all the channels. It is also possible to modulate only a subgroup of channels, or else to modulate at a frequency higher than the bit frequency, as explained in the aforementioned patent application. The length and dispersion of the compensating fiber vary accordingly.

In the examples of FIGS. 1 to 4, the compensation fiber is located in the vicinity of the regenerators. This fiber could also be placed in other positions, for example separating it into sections arranged in the amplifiers. In the embodiment of FIGS. 5 to 7, a phase modulator is considered, followed by an intensity modulator. We could also have a reverse configuration; the efficiency would be reduced, since the intensity modulation requires a "non-linear" pulse for maximum efficiency in controlling the jitter and the noise level. It is therefore preferable, as in the embodiments described above, that the signal conversion be placed before the intensity modulator. The intensity and phase modulations could also be carried out either by the same component or at the same place in the line; ie behind the conversion fiber and behind the periodic narrow filter.

Claims

1. A regenerator for receiving and regenerating a plurality of wavelength and asynchronous multiplex channels at the input of the regenerator, comprising a section of dispersive optical fiber and a synchronous modulator, the length and the dispersion of said section being chosen so to ensure the synchronization of the bit times of the channels at the input of the synchronous modulator.

2. The regenerator of claim 1, characterized in that it further comprises a second section of dispersive optical fiber at the output of the modulator.

3. The regenerator of claim 1, characterized in that the product of the length by the chromatic dispersion for the said second section of optical fiber is the opposite of the product of the length by the chromatic dispersion for the said section of optical fiber .

4. The regenerator of claim 1, 2 or 3, characterized in that the dispersive optical fiber has a negative dispersion.

5. A wavelength division multiplex transmission system, comprising a regenerator according to one of claims 1 to 4 in a position in the system where the channels are asynchronous.

6. The system of claim 5, characterized in that said section has a dispersion of sign opposite to the average dispersion in the line fiber of the transmission system.

7. A regenerator comprising a first synchronous modulator (8), a section of conversion fiber (1 1) and a second synchronous modulator (1 8), the length and the dispersion of said section being chosen so as to ensuring the synchronization of the bit times of the channels at the input of the second synchronous modulator.

8. The regenerator of claim 7, characterized in that the first modulator is a phase modulator.

9. The regenerator of claim 7 or 8, characterized in that the second modulator is an intensity modulator.

10. The regenerator of claim 7, 8 or 9, characterized in that it further comprises an amplifier (10) between the first modulator and the conversion fiber section and in that the chromatic dispersion of the conversion fiber is chosen so that the peak power of the signals in the conversion fiber is less than or equal to the output power of the amplifier.

1 1. The regenerator of one of claims 7 to 10, characterized in that the signals in the converting fiber section are soliton signals, and in that the length of the converting fiber section is a multiple of the period of soliton signals.

12. The regenerator of one of claims 7 to 1 1, characterized in that the first and the second modulator has a common clock recovery device.

13. A wavelength division multiplex transmission system, comprising a regenerator according to one of claims 7 to 12.