DE10228144B4 - An arrangement for separating channel signals of a polarization multiplexed optical signal and an optical transmission system incorporating this arrangement - Google Patents

Abstract

Arrangement for the separation of channel signals (KS1, KS2) of a polarization multiplexed optical signal (S1), which is fed into a controllable polarization controller (PS) with a downstream polarization beam splitter (PST), characterized
that at least one channel signal (KS1, KS2) has a directed error correction (FEC) and
in that at the output of the polarization beam splitter (PST) at least one module (DECOD1, DECOD2) for controlling the polarization controller (PS) is connected by decoding the directional error correction (FEC).

Description

The The invention relates to an arrangement for the separation of channel signals a polarization multiplexed optical signal according to the features the preambles of the claims 1 and 2 and an optical transmission system according to claim 10.

Out EP 1 137 308 A2 a polarization switch is known, at whose input a channel of a wavelength division multiplexed (-WDM) signal is fed to a regulated polarity controller. A polarization controller is controlled such that two signals with orthogonal polarization directions but identical data content are separated from the channel signal by a polarization beam splitter. The regulation of the polarization controller serves to set a desired power ratio at the two outputs of the polarization beam splitter. This polarization switch forms a drop circuit for one of the two orthogonal linearly polarized signals. The remaining and possibly minimal second orthogonal linearly polarized signal continues to reach a polarization beam coupler adapted to its polarization direction and is combined there with a new external signal. The new external signal has a direction of polarization which is orthogonal to the polarization direction of the signal from the polarization beam splitter to avoid crosstalk. From the polarization beam splitter portions of the two output signals are diverted and their power ratio used as a control variable for the control of the polarization controller. At most, a channel is correctly decoupled. However, this polarization switch is not suitable for a polarization multiplexed signal. Since this contains two signal channels on two nearly orthogonal polarizations, it is not possible to find a setting of the polarization plate, so that the polarization multiplexed signal is largely applied to one of the two outputs of the polarization beam splitter. For this purpose, however, the proposed control criterion (power ratio) can not be used because with an (ideal) polarization multiplex signal, the power ratio is independent of the setting of the polarization controller.

Out EP 1 009 118 A2 However, another optical demultiplexer is known in which, however, channel signals are separated by OTDM (Optical Time Division Multiplexing) transmission technology regardless of their polarizations.

For signal quality reasons, the use of directional error correction FEC (Forward Error Correction) in the data signals is often used in wavelength division multiplexed WDM transmission methods. Out DE 100 03 398 A1 For example, a transmission system for a WDM signal is known in which channel signals are coded with directional error corrections in a transmitting unit and then decoded in a receiver for optimizing the bit error rate. In addition, a high-frequency polarization modulator is provided for distributing the polarization states of the transmitted signals so as to average over the polarization mode dispersion, and thus high bit error rates occur only in a short time scale. The resulting bit error rate can then be further reduced by an FEC method.

From "Automatic Polarization Demultiplexer for Polarization-Multiplexed Transmission Systems ", F. Heismann et al., European Conference on Optical Communications, 1993, Montreux, Switzerland, pages 401-404 a simpler polarization demultiplexer is known, the receiver side a polarization controller with a downstream polarization beam splitter having. From a correlation signal of the recovered clock at the output of the receiver and the received signal, a correlation product is formed and maximized to adjust the polarizer. adversely it is also that the correlation product at specification of a pure, ac voltage-coupled pseudorandom sequence in the time average disappears, which makes the regulation difficult or impossible. By maximizing the correlation product, disturbing crosstalk occurs on. Furthermore it is disadvantageous that the two channel signals have different data rates have.

Out DE 101 47 892 A1 an arrangement for the separation of channel signals of a polarization multiplexing optical signal is known, which is fed to a controllable polarization controller with a downstream polarization beam splitter.

task The invention is an arrangement of the type mentioned above so to improve that the one separation of channel signals of a polarization multiplexed signal with little effort possible becomes. Furthermore, a rule criterion for optimum separation of Channel signals with accurate and low-noise determination of their data signals be specified.

A solution The object arises in terms of their device aspect by an arrangement with the features of claims 1, 2 and by a optical transmission system according to Claim 10.

Starting from a polarization multiplexed optical signal with channel signals, which in a is fed controllable polarization controller with a downstream polarization beam splitter, the invention provides that at least one of the channel signals has a directed error correction. In addition, at least one module for controlling the polarization controller by decoding the directed error correction is connected to one or both outputs of the polarization beam splitter.

The or the modules for decoding the directed error correction have determination units for determining a number of corrected errors from the directed error correction, which is a rule criterion for controlling the polarization controller by means of a control signal enable. This arrangement is advantageously suitable as a receiver of Channel signals for a transmission path, in which no high polarization mode dispersion occurs.

A Variant of the invention according to the preamble of claim 2 is an inventive arrangement for the separation of Channel signals of a polarization multiplexed optical signal, which in several Adjustable polarization plates with downstream polarizers is fed, wherein at least one of the channel signals a directional Having error correction and wherein the polarizers at least a module for controlling the polarization controller by decoding the directed error correction is followed.

Changes the polarization orthogonality of two original ones orthogonal polarized channel signals z. B. due to a polarization mode dispersion or polarization-dependent Losses (PDL), is an independent reclamation the polarization of these channel signals by controlling two separate Secured polarization plates. Thus the polarization plates do not track the same channel signals, the channel signals Data signals with different recognition words z. B. as overhead bits and / or with different directed error corrections e.g. B. arranged from two coding units in one of the transmission path Polarization multiplex transmitter on. To identify the two Channel signals is also the use of a pilot tone method, use different data rate or other characteristics that the two channels distinguishable, conceivable.

One Module for decoding the directed error correction has a Detection unit of a number of corrected errors of the decoded directed error correction. The number of corrected errors is a measure of Bit error rate and thereby forms a suitable control criterion for the setting the polarization controller for separating the channel signals. As targeted The rule criterion is a minimization of the determined number of corrected errors provided by a control signal supplied to the polarization controller. Therefore, the cost of the control according to the invention is very low.

In addition to an incorrect adjustment of the polarization at one or more Polarization controllers become more related to the bit error rate disturbing Suppresses effects.

In current optical transmission systems are usually already transmitting units with modules for coding a directed error correction in channel signals. The use the arrangements of the invention in such transmission systems is therefore feasible with very little effort.

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

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

there demonstrate:

1 a first arrangement according to the invention,

2 A second arrangement according to the invention.

In 1 a first arrangement for the separation of two channel signals KS1, KS2 from a polarization multiplex signal S1 is shown. This arrangement is used here as a receiver RX of a transmission system with a transmission unit TX for generating and feeding polarization multiplex signals into an optical waveguide LWL as a transmission path. In the transmitting unit TX or at least before the polarization demultiplexing of the channel signals KS1, KS2, data signals of the channel signals are coded with one or more different directional error corrections FEC (FEC1, FEC2) in a module COD. At the input of the receiver RX, a controllable polarization controller PS with a downstream polarization beam splitter PST is connected. With good setting of the polarization controller PS, the polarization states of the polarization multiplex signal are at least approximately orthogonal and mapped to the two polarization separation characteristics of the polarization beam splitter PST at its output. The output signals of the polarization beam splitter PST are further fed into two modules DECOD1, DECOD2 for decoding the error correction directed in the channel signals. From the modules DECOD1, DECOD2 are respectively control signals RS1, RS2 to the Pola PS for controlling its settings, depending on the number of corrected errors from the decoded directed error corrections returned. The modules DECOD1, DECOD2 also have a detection unit of the number of corrected errors from the decoded directed error corrections, which is minimal with optimum setting of the polarization controller.

The Using a single module DECOD1 is sufficient in the event that the channel signals KS1, KS2 at the input of the polarization controller a correct orthogonality (elliptical left / right or circular left / right or linear vertical) show their polarization vectors. The use of the second module DECOD2 serves z. B. for a double control speed or a more precise setting of the Polarizer PS or for correct and uninterrupted Adjustment of the polarization controller PS during failure / deactivation one of the channel signals KS1, KS2.

The Modules DECOD1, DECOD2 are respectively optical or electrical receivers RX1, RX2 switched. The modules DECOD1, DECOD2 can also be used in the receivers RX1, RX2 be integrated. The association between decoding modules and receivers here forms no essential feature to achieve the object of the invention.

The Modules DECOD1, DECOD2 is one unit each for minimizing the number the determined corrected error from the directed error corrections FEC downstream or integrated, the control signals RS1, RS2 ever for generate the polarization controller PS. The detection speed The modules DECOD1, DECOD2 are high enough, so that usual disturbances as well as slow property changes in the transmission line do not affect the scheme.

In 2 is a variant of the receiver RX according to 1 shown. The signal S1 is fed to a power divider with two outputs, to each of which a polarization controller PS1, PS2 is connected. The two polarization controllers PS1, PS2 are each followed by a module DECOD1, DECOD2 for determining the directed error corrections FEC of the channel signals KS1, KS2.

In addition to Decoding for the separation of the channel signals and with a required predefined Assignment of the channel signals KS1, KS2 to the receivers RX1, RX2 should have a Detection of the channel signals KS1, KS2 or their data done. This is most often coded by recognition words in reached the data signals contained in the channel signals KS1, KS2. These recognition words are determined in the modules DECOD1, DECOD2 for decoding and possibly compared with unknown distinct pairs of recognition words, so that the same channel signal KS1 or KS2 not on both receivers RX1 and RX2 arrives. A code predefined from the module COD the channel signals KS1, KS2 with two different directional Error corrections FEC as recognition words can also provide information about the identity provide the channel signals.

The Polarization controllers PS1, PS2 are each linear polarizers POL1, POL2 downstream. This will unpolarized light components such as ASE (amplified spontaneous emission), favorably suppressed.

Sufficient Again, the use of a single module DECOD1 or DECOD2 for controlling both polarization controllers PS1, PS2 with alternating Decoding the directional error correction corresponding to the channel signals and with alternate determination of the number of corrected errors.

The polarization multiplex signal S1 may also be a channel of a wavelength division multiplexed (WDM) signal. In this additional wavelength division multiplexing technique, the polarization controller is PS or PS1, PS2 according to 1 or 2 a wavelength demultiplexer DEMUX upstream. At each output of the wavelength demultiplexer DEMUX one receiver RX can be connected in each case.

Claims (10)

Arrangement for the separation of channel signals (KS1, KS2) of an optical polarization multiplex signal (S1), which is fed into a controllable polarization controller (PS) with a downstream polarization beam splitter (PST), characterized in that at least one channel signal (KS1, KS2) has a directional error correction (FEC) and that at the output of the polarization beam splitter (PST) at least one module (DECOD1, DECOD2) for controlling the polarization controller (PS) by decoding the directional error correction (FEC) is connected. Arrangement for separating channel signals (KS1, KS2) of a polarization multiplexed optical signal (S1) which is fed into a plurality of controllable polarization controllers (PS1, PS2) with downstream polarizers (POL1, POL2), characterized in that at least one channel signal ( KS1, KS2) has a directed error correction (FEC) and that the polarization controllers (PS1, PS2) at least one module (DECOD1, DECOD2) for controlling the polarization controller (PS1, PS2) by decoding the directed error correction (FEC) is followed. Arrangement according to claim 1 or 2, characterized that the modules (DECOD1, DECOD2) are a determination unit of a number corrected errors of the decoded directed error correction (FEC) and that the number of corrected errors has a minimum value at optimum polarizer setting. Arrangement according to one of the preceding claims, characterized in that in each case the polarization controller (PS, PS1, PS2) a control signal generated in the modules (DECOD1, DECOD2) (RS1, RS2) supplied is and that the control signal (RS1, RS2) is a rule criterion of Polarization controller (PS1, PS2) according to the number of corrected Has errors. Arrangement according to one of the preceding claims, characterized characterized in that the channel signals (KS1, KS2) different directed error corrections (FEC1, FEC2). Arrangement according to one of the preceding claims, characterized characterized in that the channel signals (KS1, KS2) with data signals different recognition words exhibit. Arrangement according to one of the preceding claims, characterized in that the modules (DECOD1, DECOD2) optical or electrical receiver (RX1, RX2) are switched or that the modules (DECOD1, DECOD2) in the receivers (RX1, RX2) are integrated. Arrangement according to one of the preceding claims, characterized characterized in that the optical polarization multiplexed signal (S1) is a channel of a WDM signal. Arrangement according to claim 8, characterized that the polarization controller (PS, PS1, PS2) a wavelength demultiplexer (DEMUX) is connected upstream. Optical transmission system with an arrangement according to claim 1 or 2.