DE102004043530A1 - Wavelength multiplexed optical transmission system with serial connected fibres modifies spectral tilt at transitions to minimise non linearity and dispersion - Google Patents

Abstract

A wavelength multiplexed optical transmission system with serial connected fibres uses spectral tilt filters, attenuators, amplifiers or add drop modules to modify the spectrum profile or tilt at transitions between different fibre types so that non linearities and dispersion effects are minimised.

Description

The The invention relates to a transmission system for a optical signal according to the preamble of claim 1.

nowadays be high range for a transmission of optical signals, in particular in WDM technology (WDM = wavelength division multiplex) by making noise and other e.g. non-linear interference effects repressed or at least minimized.

This is e.g. the case with a transmission system with several serially connected optical transmission fibers, the certain have optical physical properties such as attenuation, dispersion, etc. To guarantee a desired one Spectrum profiles of the optical signal - in terms of power, signal-to-noise ratio or bit error rate - on a receiver of the transmission system be along the transmission line In-line amplifier, like optical fiber amplifiers or Raman amplifier, arranged. With a Raman amplifier can however due to the reinforcement profile pump signals the amplified optical Signal channels with a slightly tilted spectral power distribution. Such an effect can also be achieved without a Raman amplifier due to an intra-band Raman effect occur alone in the signal band. Will not such an effect desired - in particular due to the limited dynamics of a receiver -, must be before receiving the optical power adjustment means adjust the power of the channels. A solution to Adjustment of services or their course consists in the entrance a transmission system, e.g. at the first inline amplifier, or distributed over several inline amplifiers, one Pre-emphasis by an adaptation or tilting of the local input signals perform, for example, one as possible flat spectrum of the signal power, signal-to-noise ratio OSNR or bit error rate BER of the channels at the receiving end of the transmission path allows.

Such spectral profile changes or tilting of the power, the signal-to-noise ratios or the bit error rate of the channels of the WDM optical signal also caused by other effects than Raman scattering of a Raman amplifier (Intraband Raman scattering in the signal band, curved fiber attenuation in the signal band) Signal band, ...). It can other non-linear effects in the transmission of an optical Called four-wave mixing, self-phase modulation, Cross-phase modulation, crosstalk, etc.

1 shows, for example, an attenuation ATT (in dB / km) of a conventional optical fiber as a function of the wavelength λ (in nm) of a transmitted optical signal. Non-linear effects of Rayleigh Scattering (RSA), OHA (OH absorption), BL (Bending Losses) and SABS SiO2 absorption are present in different spectral regions in different spectral regions and can severely affect transmission. In the range of 1525-1565nm (C-band) and 1565-1610nm (L-band) there is also a curved attenuation ATT.

• – SSMF (Standart Single Mode Fiber, gleich als NDSF),
• – MDF (Medium-Dispersion Fiber),
• – DSF (Dispersion-shifted Fiber),
• – NZDSF– (Non-Zero-Dispersion-Shifted Fiber, negative dispersion in C-Band),
• – NZDSF+ (Non-Zero-Dispersion-Shifted Fiber, positive dispersion in C-Band), z.B. LEAF (Large Area Fiber) der Firma Corning, True Wave Classic oder True Wave RS der Firma Lucent, ...
• – etc

Further, nowadays, the transfer media such as optical fibers have new properties such as reducing spurious dispersion for a particular type (return-to-zero or non-return zero) of spectral signal ranges (C, L band) to achieve longer range , As a known optical fiber standard, for example:

• SSMF (Standard Single Mode Fiber, equal to NDSF),
• - MDF (Medium-Dispersion Fiber),
• DSF (dispersion-shifted fiber),
• NZDSF (non-zero dispersion-shifted fiber, C-band negative dispersion),
• - NZDSF + (non-zero dispersion-shifted fiber, positive dispersion in C-band), eg LEAF (Large Area Fiber) from Corning, True Wave Classic or True Wave RS from Lucent, ...
• - Etc

2 represents the dispersion DISP (in ps / nm km) of some of this fiber as a function of the wavelengths λ (in nm), in particular for C and L band optical signals. Thus it can be determined to what extent the slope of the dispersion DISP and the dispersion zero is different between transmission fiber.

at a transmission optical signals via The fibers of the first type SSMF are basically non-linearities Signal quality spectral do not affect much (i.e., all signals are affected approximately equally). However, for a conventional one WDM signal (C and L band) a strong four-wave mixing in one fiber of the type DSF or NZDSF-, where the dispersion zero the fiber is between 1550 and 1565 nm. Below 1540 nm remains the four-wave mixing lower. An OSNR or performance-based Pre-emphasis can tilt the performance of input signals and continue to be used to compensate for non-linearity.

Non-linear effects will now occur in the other fiber types NZDSF +, in particular because the dispersion zero varies between 1525 and 1400 nm, depending on the fiber type. In this Fa At 1530 nm, the dispersion at 1530 nm is smaller than at 1560 nm, and for the same channel power at 1530 nm, noise due to non-linearities is higher than for the same channel power at 1560 nm. This effect is particularly pronounced for TWC (True Wave Classic ^© ) fibers, which has a dispersion zero at 1525 nm, and therefore, channels at 1530 nm are severely degraded mainly due to four-wave mixing.

task The invention is a system for transmitting optical signals over different types of fibers indicate that a high range is achieved.

A solution The task is carried out by a transmission system with the features of claim 1.

advantageous Further developments of the invention are specified in the subclaims.

outgoing from a transmission system for an optical Wavelength division multiplexed (WDM) signal with several serially connected transmission fibers to which Power adjustment means for modification, preferably for tilting, the spectrum profile of the transmitted optical signal are connected, with successive transmission fibers have different fiber types, according to the invention in Passage between two consecutive transmission fibers with different Fiber types include the passageway or previous power adjusting means re-adjusted that along the transmission system disturbances of the Spectrum profiles at least by nonlinearities and dispersion effects be minimized.

advantage this transmission system is that also in addition to a conventional preemphasis from a transmission system input side Inline amplifier a fine further Preemphase sections in any inline amplifiers of the transmission system depending on a required adaptation of the channel power for a fiber type - or signal-to-noise ratios, bit error rate, Q-factor, etc. - is performed. This further finer preemphasis is e.g. through a tilt of the spectrum profile of the optical signal at the input of a fiber - as such called pre-tilting - or at the output of a fiber - as so-called residual tilting. Mostly the pre-tilting comes along one or more inline amplifiers and takes place depending on the type of nearest fiber, i. in front or in the passage of the optical signal over two fibers different Types may be reset. The residual tilting can be at the output a fiber, a fiber section or the transmission system e.g. by means of a local inline amplifier determined and possibly compensated. Mostly are between Fibers of different types or generally along the transmission system Power adjustment means such as attenuators, adaptive tilt filters, add-drop modules, inline amplifiers, etc. switched to these places and possibly performance monitors. That it be for the present invention no further or a minimum number of additional Adjustment or monitor components in the transmission system needed to the - fine - preliminary or residual tilting perform or to compensate.

Also the power setting means may comprise at least one tilt spectral filter is what different tilting in different have spectral passbands. This allows different spectral Sub-bands of one optical signal separated from each other and also with different Tilt values are adjusted.

Becomes a tilt on an inline amplifier to suppress a Nonlinearity set, may be the closest Inline amplifier one Tilting e.g. the signal-to-noise ratio of the take place optical signal. To avoid such effects will first set a pre-tilt to inline amplifiers such that channels at the entrance to a next transmission section the same Worsening in the bit error rate or in the so-called Q-factor Experienced. This means that the channels, the less nonlinear Distortion should be for it experience a deterioration in the optical signal to noise ratio.

The This is achieved by the (pre-) tilting of the spectrum, to Compensation of the fiber tilt generated by the spectral attenuation and the tilt by the Raman effect, is distributed so that a part of the necessary compensation tilt at the fiber input is set and part of the tilt at the fiber output than Residual tilt remaining remains. This residual tilt leads to a tilt of the signal-to-noise ratios in the nearest amplifier. The optimum between pre- and residual tilt therefore depends on the spectral curve the dispersion and scaling of nonlinearity with the Dispersion.

One embodiment The invention will be explained in more detail below with reference to the drawing.

there shows:

3 an average bit error rate at different input channel powers and different pretranslations in different sub-bands of the transmitted optical signal along 7 fiber sections,

4 : Tilts of the channel power spectrum over the transmission system with 7 fiber sections and 8 amplifiers.

to Description of the tilt control according to the inventive transmission system will use data from the "True Wave Classic "fiber (TW Classic fiber or TWC) made by Lucent Technologies.

More generally, a non-linear power limit for a disturbing four-wave mixing FWM may be defined as a function of the dispersion D (λ): FWM ≈ D (λ) 2

Thus, the pre-tilting depends on re-tilting the power of channels from the slope of the curve dispersion, such as in 2 , plotted against wavelength λ of a channel and from the distance to the limiting power limit. This power limit depends on the number of transmission sections, for example in a transmission section with a TWC fiber would be a power limit for 50 GHz distance of the channels at the blue end of the C-band at about 1530 nm at about 5 mW and 10 transmission sections then at 0.5 mW per transmission section (more generally approx. 1 / N for N transmission sections).

In dispersion curves of the fiber types of 2 however, different types of nonlinearities can be detected along the wavelengths. For example, the cross-phase modulation XPM is proportional to the dispersion D (λ) in contrast to the four-wave mixing FWM, which is proportional to the square of the dispersion D (λ). Therefore, the tilt and possibly the pre-tilt for nonlinear limited systems must then be set accordingly.

3 shows for 3 different channel powers P / Chan (left at +0.4 dBm, center at +1 dBm and right at -1 dBm) the logarithmic bit error rates log (BER) of individual spectral subbands CiCj (i, j = 1, 2, ... , 8) of a WDM signal with 80 channels after transmission through 7 sections each with a "TW Classic" fiber The designation C1C5 corresponds to channels in the range of wavelengths around 1530nm, C4C8 around 1560nm and C2C6 and C3C7 are within the previous ones Subcibles C1C5, C4C8, that is, an optical signal in C-band is taken into account here, where at low wavelengths nonlinear perturbing effects can be coined.The dark central curve "Mean_All" shows the average value of the logarithmic bit error rate log (BER ) for all channels. The pre-tilt "pretilt reduction" is varied by means of ten values "Action" = -1, -0.9, -0.8, ..., -0.1, 0 dB / THz. Only in the case of a pure noise limitation with a channel power P / Chan of -1 dBm per channel, there is no improvement with respect to the average bit error rate log (BER) by reducing the pre-tilting "pretilt reduction". "Action" = -0.2 to -0.3 dB / THz led to an improvement of the average bit error rate in both other cases, ie P / Chan = 0.4 dBm and P / Chan = 1 dBm (see the minimum for the curve "Mean_All ").

In 4 Fig. 3 shows the tilt Tilt in dB / THz of the channel power spectrum over a transmission system with 7 fiber sections and 8 amplifiers along the route. Both points OLI = 1, 2 designate an input and an output of an amplifier, here the booster of the transmission system. The point OLI = 2 also designates the input to the first fiber. Further points denote in pairs further inputs and outputs of the nearest inline amplifiers, or inputs into one fiber. Overall, this tipping pattern over the distance is plotted for six different pre-tilts -0.3, -0.6, -1.2, -1.6, -2.0 dB / THz at the booster input. Here, the six tilt profiles are called PT1, PT2, PT3, PT4, PT5, PT6 (PT1 = upper curve and PT6 = lower curve).

The Upper curve PT1 shows a previously used optimization with full Pre-tilting at the output of the booster (= input to the fiber at OLI = 2) and about no tilting at the output of the fiber (= input the next Inline amplifier at OLI = 3). The lower curve PT6 shows the opposite no pre-tilting at the output of the booster (= input to the fiber at OLI = 2) and full residual tilt at the fiber output (= input to the next inline amplifier at OLI = 3).

On the basis of in 3 plotted BER (BER) for pre-tilt between -1.0 and 0 dB / THz, it should be noted that the optimum bit error rate BER over all channels for the special case of fiber type "TW-Classic" is approximately reached when pre-tilting at the input of the fiber By further reducing the pre-tilt, the bit error rate BER for the blue channels in the L-band degrades because the transmission of the signals in the channels is noise-limited, ie an optimum between non-linear Limitation and noise limitation is achieved.

It can be shown that the top curve PT 1 is optimal for a DSF and an LS fiber, that both curves PT2, PT3 are optimal for a SSMF and MDF fiber, that both curves PT4, PT5 optimally for "NZDSF + "Fiber is and that the lower curve PT6 is optimal for a TW Classic fiber according to 3 is.

In summary, it is possible from 2 and 4 to infer which pre-tilt is optimal for a particular fiber type. 3 shows the special case with the example of the TWC fiber. In contrast, shows 4 In general, the possibilities of how the pre-tilting in the system can be adjusted and as a measurement, that also the desired tilting can be set in about all sections.

Claims (10)

Transmission system for an optical wavelength division multiplexed (WDM) signal having a plurality of serially connected transmission fibers, to which power adjustment means for changing, preferably tilting, the spectrum profile of the transmitted optical signal are connected, in that successive transmission fibers have different fiber types, characterized in that in the passage between two successive transmission fibers having different fiber types, a power adjustment means lying in the passage or previous is adjusted such that along the transmission system, spectrum spectrum disturbances are minimized at least by nonlinearities and dispersion effects. transmission system according to claim 1, characterized in that the power adjusting means a spectral tilt filter, an attenuator, an inline amplifier, a Add-drop module, etc. is or is part of it. transmission system according to claim 2, characterized in that the power adjusting means at least one spectral tilt filter is different Tilts in different spectral passbands having. transmission system according to one of the claims 1 to 3, characterized in that before the entrance of the optical Signal in a transmission fiber the power adjustment means pre-tilt the spectrum profile of the optical signal in dependence the dispersion zero of a transmission fiber and causes their dispersion profile. transmission system according to one of the claims 1 to 4, characterized in that channels of the transmitted optical signal at the entrance of one of the transmission fibers have the same degradation of the bit error rate or the Q-factor. transmission system according to one of the claims 1 to 5, characterized in that a power adjusting means for setting a residual pretilt of the spectrum profile at least at the end of one of the transmission fibers connected. transmission system according to one of the claims 1 to 6, characterized in that an optimum for the setting of pre- and residual tilting of a spectral profile of the dispersion and is dependent on a scaling of the nonlinearity with the dispersion. transmission system according to one of the claims 1 to 7, characterized in that the power adjusting means a tilt of the spectral spectrum profile of the optical signal to compensate for a residual Raman effect at the end of one of transmission fibers causes. transmission system according to one of the claims 1 to 8, characterized in that the transmission system is not noise-limited Has sections. transmission system according to one of the claims 1 to 9, characterized in that the power adjusting means a rough and a fine adjustment to the preemphasis of the optical Signal or to minimize residual nonlinear effects.