DE10130993C1 - Arrangement for optimizing quality of wavelength division multiplex signal with residual dispersion has decoupler, module for adjusting residual dispersion of signal, signal quality detector - Google Patents

Abstract

The arrangement has a decoupler (K) at a measurement point along a transmission path for decoupling at least one component of the wavelength division multiplex signal followed by a module (DM) with a variable dispersion component for adjusting the residual dispersion of the wavelength division multiplex signal and a device (E) for determining the signal quality to be optimized. AN Independent claim is also included for the following: a method of optimizing signal quality of wavelength division multiplex signal with residual dispersion in optical transmission system.

Description

The invention relates to an arrangement and a method for Optimization of the signal quality of a residual dispersion having wavelength division multiplex (WDM) signal in one optical transmission system.

When WDM signals are transmitted through optical fibers occur signal distortions z. B. by nonlinear perturbations on. With an optical transmission system, these must be Effects are determined and further minimized. Therefore are measuring instruments and corresponding measuring methods of Quality characteristics of a signal developed.

In particular, effects such as dispersion affect GVD (Group Velocity Dispersion), self phase modulation SPM (Self Phase Modulation) and Cross Phase Modulation XPM (Cross Phase Modulation) the signal quality of all channels transmitted WDM signal. These effects occur depending on the Wavelength of the transmitted signal channel different strongly on. With a WDM or DWDM (Dense Wavelenght Division multiplexing) transmission system will be many channels over a certain bandwidth, for example in the C- and L- Tape. This is why additional DCF Fibers (Dispersion Compensation Fiber) over the Intermediate transmission path to dispersion effects over a portion of the bandwidth of the WDM signal compensate. In this context, DE 196 02 433 C2 to refer to the use of multiple DCF fibers with different spectral compensation ranges for individual channel dispersion compensation is known.

EP 0 685 947 A1 also describes a method for compensation the self-phase modulation SPM and the dispersion GVD  proposed. Because SPM is a narrowing of a pulse signal and GVD causes broadening of the pulse signal these effects by using dispersion-compensating DCF fibers and under certain Compensate for conditions. The SPM effect also distorts the signal depending on its performance. That's why they are Repeater controlled so that distortion caused by SPM can be minimized without high losses in performance occur (see EP 0 685 947 A1, column 2, lines 49-58 and Column 3, lines 1-28). But for high performance other nonlinear disruptive effects such. B. XPM on which is not taken into account in this known method were.

Other methods allow compensation for the Residual dispersion of a transmitted WDM signal by a electrical conversion of the optical signal and on by a phase correction of the electrical broadband Signal. Some variants of this method are out EP 0 954 126 A1 and EP 0 844 752 A2 are known. The advantage lies in saving the effort of many Compensation fibers DCF for all channels or Subbands of the WDM signal. With an extension, e.g. B. at Splitting the transmission link, therefore, need more optical-electrical conversion units used become. These variants mainly compensate for the Residual dispersion while compensating for the SPM effects or, especially with high signal powers, the XPM effects are not given any hints.

DE 199 14 793 A1 describes a method and an arrangement for measuring the signal quality in a transmission system known with a transmission link. On Dispersion compensator or emulator with a downstream Coupler is inserted in the transmission link. The coupler is a device for determining the signal quality of a coupled WDM signal connected.

The object of the present invention is therefore to a method for the determination and compensation of GVD, SPM and XPM effects for optimizing the signal quality to specify a transmitted optical WDM signal.  

This task is accomplished through an arrangement and a process with the characteristics of Claims 1 and 5 solved.

Appropriate further training are in the dependent Described claims.

According to the invention, the residual dispersion is covered by GVD Consideration of SPM and XPM effects on one compensated for any location on the transmission path, so that Signal quality of all channels of a WDM or DWDM signal is optimized. It is advantageous that when expanding the Transmission system these effects at any location one Transmission path can still be compensated. This does not require additional installation of a new complex Component, but only a single measurement of the Residual dispersion with simultaneous determination of the optimizing signal quality.

For the optimization of the signal quality is in the arrangement according to the invention a module with a tunable Dispersion compensation is provided so that one of the optimal Signal quality corresponding dispersion compensation on Optimally selected measuring location of the transmission path and is interposed accordingly. This allows the Course of the dispersion along the transmission path be optimized.

When optimizing the residual dispersion, statements about the other effects SPM and XPM in relation to the Signal quality made. These statements are based on the situation the optimum of the signal quality, which is a function of the Residual dispersion is determined.

The signal quality of the arrangement according to the invention is as Bit error rate, as a Q factor, as a signal-to-noise ratio or  as the number of corrected bits for forward error correction through a module for tunable dispersion compensation downstream facility determined.

The inventive method for optimizing the Signal quality through tunable dispersion compensation takes place for all or some channels of the WDM signal. This is achieved by channel separation of the transmission path decoupled WDM signal realized.

A corresponding strengthening or weakening of decoupled WDM signal is provided so that the Measurement sensitivity of the method is increased.

The arrangement can thus be integrated in a measuring device a possible commissioning monitoring at any point Transmission path is feasible.

An embodiment of the invention is based on the Drawing described in more detail. Show:

Fig. 1 is a schematic representation of the arrangement according to the invention,

Fig. 2 shows the course of the signal quality as a function of the residual dipersion.

The arrangement according to the invention for optimizing the signal quality by means of tunable dispersion compensation is shown schematically in FIG. 1. A WDM signal S - or a portion thereof - is decoupled at one point in a transmission link LWL by a decoupling device K and fed into the arrangement. The input signal is fed to an amplifier EDFA (fiber amplifier), the output signal of which comes to a variable optical attenuator VOA to increase the measuring sensitivity. After this amplification, the signal undergoes variable dispersion compensation by means of a module DM with tunable dispersion compensation. With the help of this module DM, which an operator adjusts accordingly during start-up, the residual dispersion that has accumulated along the transmission path can be varied. The module DM can have several dispersion-compensating fibers DCF, which can be interconnected manually or by optical circuits for variable dispersion compensation, and / or tunable dispersion-compensating fiber Bragg gratings or filters and / or integrated optical elements, in particular Mach-Zender interferometers or ring resonators , exhibit. Then all channels are demultiplexed by a DEMUX, e.g. B. by means of a tunable optical filter, separately and fed into a device E for measuring the signal quality. The signal quality of each channel is determined as a bit error rate BER, as a Q factor Q, as a signal-to-noise ratio OSNR or as a number of corrected bits with Forward Error Correction FEC.

The dispersion compensation of this arrangement serves the accumulated dispersion of the transmission fiber at the measuring location compensate. Adequate compensation follows Achieve optimum signal quality for all channels. You can then use adequate dispersion compensators Modules from an operator at the measuring point of the transmission link interposed during and after commissioning become.

The total dispersion of a a chain of amplifiers having transmission path be determined by an appropriate measuring device.

For the Fig. 2, the Q factor as a parameter for the signal quality of a WDM signal with 10 Gbit / s is selected NRZ coding at 21 dBm. The course of the Q factor Q is shown as a function of the accumulated residual dispersion RD when adjusting the tunable dispersion compensation of the arrangement according to the invention for one channel. As the so-called optimum signal quality, the curve shows a maximum with a residual dispersion value of approx. -200 ps / nm. The limiting effects of dispersion GVD and self-phase modulation SPM are decisive for this residual dispersion value. If the channel power is low, these two effects have the opposite effect. The width of a pulse signal is increased by GVD and vice versa by SPM. However, this only applies up to a performance threshold above which the XPM effect reappears. Then the maximum of the course of the Q factor will be close to the full compensation at 0 ps / nm with limited system performance by XPM. To minimize the XPM effects, the channel powers can then be reduced or larger channel spacings can also be used. The method according to the invention for optimizing the signal quality by means of tunable dispersion compensation thus delivers a clear statement by the position of the optimum of the Q factor, so that the signal distortions can be suppressed by the compensation of the determined effects GVD, SPM and XPM.

The commissioning measurement in the method according to the invention takes place for all or some channels of the transmitted WDM Signals and therefore enables optimization of the Signal quality for the entire transmission band or for certain subbands.

The examination of the channels is particularly important with WDM systems at the edge or in the middle of the transfer belt as well as the Examination of the channels with the largest or the smallest Intensities make sense. At the edge of the transfer belt the fiber dispersion reaches its extreme value, are against Signal distortion caused by XPM in the middle of the Transmission band the strongest. The channels with the highest Performance are closer to the SPM limit while the channels are using the lowest power rather through signal-to-noise ratios OSNR can be limited.

Claims (8)

1. Arrangement for optimizing the signal quality of a wavelength division multiplex (WDM) signal having residual dispersion (RD) in an optical transmission system, characterized in that
that in a measuring point provided along a transmission path (LWL) of the transmission system, a decoupling device (K) for decoupling at least a portion of the WDM signal is switched on, which has a module (DM) with variable dispersion compensation (DC) for adjusting the residual dispersion (RD) of the WDM signal is connected downstream, and,
that the module (DM) is followed by a device (E) for determining the signal quality to be optimized. 2. Arrangement according to claim 1, characterized in
that the module (DM) has a plurality of dispersion-compensating fibers (DCF) which can be interconnected manually or by optical circuits for variable dispersion compensation, and / or
that the module (DM) has tunable dispersion-compensating fiber Bragg gratings or filters, and / or
that the module (DM) has integrated optical elements, in particular Mach-Zender interferometers or ring resonators. 3. Arrangement according to claim 1 or 2, characterized in that
that a demultiplexer (DEMUX) for channel separation of the WDM signal is switched on between the module (DM) and the device (E) and,
that a tunable optical filter is provided as a demultiplexer (DEMUX), and,
that the device (E) means for determining the signal quality of each channel of the WDM signal as a bit error rate (BER), as a Q factor (Q), as a signal-to-noise ratio (OSNR) or as a number of corrected bits in forward error correction (FEC ) having. 4. Arrangement according to one of the preceding claims, characterized, that between the decoupling device (K) and the module (DM) a fiber amplifier (EDFA) and a variable optical Attenuators (VOA) are connected in series. 5. A method for optimizing the signal quality of a wavelength division multiplex (WDM) signal having residual dispersion in an optical transmission system, characterized in that
that at least a portion of the WDM signal coupled out of the transmission link is subject to a tunable dispersion compensation,
that the channels of the decoupled WDM signal are separated, and
that the signal quality of each channel is determined for different dispersion compensations and a dispersion compensation corresponding to the optimal signal quality is optimally selected and interposed at the measuring point of the transmission path. 6. The method according to claim 5, characterized in
that the signal quality is determined as a bit error rate (BER), as a Q factor (Q), as a signal-to-noise ratio (OSNR) or as a number of corrected bits in forward error correction (FEC), and
that the signal quality of all or some channels of the WDM signal is determined as a function of the residual dispersion and is optimally chosen by the tunable dispersion compensation. 7. The method according to claim 5 or 6, characterized, that the WDM signal is a gain and / or Attenuation to increase the sensitivity before the tunable dispersion compensation. 8. The method according to claim 5 or 6, characterized in that
that when optimizing the signal quality of the WDM signal by means of tunable dispersion compensation, cross-phase modulation (XPM), self-phase modulation (SPM) and dispersion (GVD) effects occurring in the transmission link are determined, and
that the position of the optimum of the signal quality as a function of the residual dispersion provides information about which effects are decisive between (XPM) or (SPM, GVD), and
that the effects (XPM, SPM, GVD) are compensated for by the tunable dispersion compensation depending on the power of the transmitted channels of the WDM signal, so that the signal quality of all channels is optimized.