DE102006048733A1 - Optical transmission line's polarization mode dispersion determining method, involves determining polarization mode dispersion of transmission line from preset representations of partial signals to orthogonal polarized signal portions - Google Patents

Abstract

The method involves dividing two signal portions (S1a, S1b) with predetermined orthogonal polarizations into two optical signals. The run time difference is determined between the optical signals. Polarization mode dispersion of an optical transmission line is determined from the predetermined representations of the partial signals to orthogonal polarized signal portions, where the predetermined representations of the partial signals on orthogonal signal portions differ from each other. An independent claim is also included for an arrangement for determining the polarization mode dispersion of an optical transmission line.

Description

The The invention relates generally to optical data transmission, and more particularly a method and apparatus for measuring polarization mode dispersion an optical transmission path.

In optical waveguides can polarization mode dispersion (PMD) affect the quality of transmission. PMD is caused by local birefringence of the optical fiber and its random Orientation over causes the fiber, resulting in a frequency and polarization dependent transit time of the signal or signal components. PMD first order can through the two major polarization axes (PSP; Principal State of polarization) and the transit time difference (DGD; differential Group Delay) between the PSPs. The two PSP are characterized in that they have a frequency independent in the first order term have. The PMD vector is the product of slow PSP and DGD. PMD higher Order can be described by a frequency-dependent PMD vector become.

A rough estimate stating that in the transferred Signal pulse distortion and thus performance degradation of the transmission system occur if the propagation delay of individual signal components exceeds 20% of the bit duration. For a high bit rate signal transmission Thus, an accurate knowledge of the PMD of the transmission path is necessary. Especially is on older links often one Compensation of the PMD required. Because the PMD vector is affected by external influences such as temperature and mechanical influences constantly changing dynamic compensators needed for PMD compensation. While PMD compensators first Order can be adjusted by means of a suitable feedback can, will for the Operation of complex broadband or multi-channel compensators due the plurality of adjustable degrees of freedom one on the current PMD characteristics of the fiber based control of the compensator necessary. This in turn requires a continuous measurement of the PMD vector without interruption of the data signal.

Various methods for measuring the PMD vector without interrupting the data signal are already known. For example, it is off IEEE Photonics Technology Letters, Vol. 14, No.3 March 2003 (G. Bosco, "Pulsewidth Distortion Monitoring in a 40 Gbps Optical System Affected by PMD" ) a frequency-based method is known in which the transmitted data signal is measured spectrally resolved by means of a narrow-band tunable filter. The polarizations of the individual spectral components rotate - as viewed on the Poincarékugel - around the desired PMD vector. However, the required complicated tunable narrowband optical filter is a significant disadvantage of this arrangement.

Furthermore, it is off DE 101 644 97 a time-domain method for measuring and compensating the PMD is known, in which the data signal is guided on the receiving side by means of a polarization controller on a polarization beam splitter. By means of an iterative algorithm, the signal components in the two PSPs are aligned with the main axes of the polarization beam splitter. From the delay difference between the signals at the outputs of the polarization beam splitter, the DGD can be determined. The disadvantage of the method is the time-consuming iterative search for the optimal setting of the polarization controller.

Of the The present invention is therefore based on the object, a way to show how the measurement of the polarization mode first-order dispersion an optical transmission path without interruption of the data signal to improved and / or simplified Way can be done. Another object of the invention is a Arrangement and method for measuring PMD of first order in transmission an optical signal.

The The above-mentioned technical problem is solved by a method according to claim 1 and an arrangement according to claim 9 solved. Advantageous embodiments and further developments are the subject of the respective subclaims.

One inventive method for determining the first-order polarization mode dispersion of a predetermined optical transmission path Accordingly, provides an optical signal through the given optical transmission path and the received optical signal into N partial optical signals split, where N is greater or is equal to three. For this purpose, for example, a conventional Power divider with N outputs be used. Furthermore, the method provides, each of the optical Partial signals, preferably by means of a polarization controller on to map two orthogonally polarized signal components, and the orthogonal polarized signal components in a pair of optical signals with a first optical signal in a first signal path and a second split optical signal in a second signal path, wherein splitting the N partial optical signals, preferably by means of a Polarization beam splitter takes place. The procedure continues before, for each of the N pairs of optical signals the transit time difference between the first optical signal in the first signal path and the second determine optical signal in the second signal path.

Of the Term "orthogonal polarized "means in this connection, that with a linear combination of the two orthogonal polarizations represent any polarization leaves. The exact orientation of the orthogonal polarizations on the the sub-signals are mapped, is preferred by the orientation the main axes of the polarization beam splitter in the respective signal path certainly.

The Inventors have recognized that at least three different given images of the sub-signals on orthogonally polarized Signal components to which the optical sub-signals, for example be imaged by means of a suitable polarization controller, and the at least three determined transit time differences the polarization mode dispersion first order can be determined. Accordingly the method further contemplates determining polarization mode dispersion the optical transmission path from the N given mappings of the sub-signals to orthogonal polarized signal components and the N determined transit time differences in front. The method provides the determination of the three-dimensional PMD vector, through which the polarization mode dispersion first order is clearly defined.

By the use of more than three optical branches, i. by splitting of the received optical signal into N partial optical signals with N greater than three, is reduced due to averaging the measurement errors and thus increases the accuracy of measurement.

at the inventive method must given images of the sub-signals on orthogonally polarized Signal components are not tuned, but can be fixed, which is particularly advantageous no expensive adjustable polarization controller to carry out of the procedure are required. Accordingly, the procedure looks prefers that the mapping of the N partial optical signals on orthogonally polarized signal components fixed by N Polarization controller takes place.

To the Determining the transit time difference between the first and second optical signal to which each of the N partial optical signals is divided is preferably the first optical signal in a first electrical signal and the second optical signal in a second converted electrical signal and the two electrical signals fed to an evaluation unit, which determines the transit time difference from the two signals.

The In particular, the invention provides torque formation and cross-correlation function as two alternative methods for determining the transit time difference in front. Accordingly, the transit time difference can be calculated via the cross-correlation function KKF (τ) = ∫Tna (t) * Tnb (t + τ) dt, where Tna (t) and Tnb (t) each optionally one of the signals of a denote the N signal pairs, or the determination of the first Moments of each received by the evaluation unit data signal determined become. In the determination of the cross-correlation function results in the transit time difference from the position of the maximum. When determining the first moments, the transit time difference results from the difference the normalized first moments.

The Determining the transit time difference by means of the cross-correlation function particularly advantageously includes the deceleration of the first or second optical signal, the delay preferably by the Evaluation unit is controlled. The difference in transit time results from the setting of the delay element, as soon as the maxiumum of the cross-correlation function is at τ = 0.

In an alternative embodiment The first and the second optical signal are first in a first and second electrical signal converted and one of these opposite to electrical signals delayed the other, the delay again preferably controlled by the evaluation unit.

A inventive arrangement for determining the first-order polarization mode dispersion of a predetermined optical transmission path from an optical signal passing through the optical transmission path has, includes a power divider with N outputs with N greater than or equal to three, and N downstream signal branches, each with a the N outputs of the power divider are connected. According to the invention, everyone has the N signal branches a polarization controller for imaging a optical signal to two predetermined orthogonally polarized signal components, a polarization beam splitter associated with the polarization controller for splitting the two orthogonally polarized signal components in two optical signals with a first and a second output, as well as with the first and the second output of the polarization beam splitter connected means for determining the transit time difference between a first and a second optical signal. The inventive arrangement is particularly suitable for carrying out the above-described Process.

The polarization beam splitters are preferably designed to convert an optical signal, which can be understood as a superposition of two signal components in orthogonal polarizations, into two signals in split two separate optical signal paths. The inventive arrangement thus advantageously forms a polarization diversity receiver which separates the optical signal into at least three pairs of signal components. Each of the pairs of signal components is composed of a signal component in a first polarization defined by the first main axis of the polarization beam splitter and the signal component in the polarization orthogonal thereto and defined by the second main axis of the polarization beam component. The transit time difference between the two signal components supplies a component of the PMD vector. The measured component of the PMD vector is determined by the setting of the polarization controller and the orientation of the subsequent polarization beam splitter. With three pairs of signal components in orthogonal polarizations, the complete three dimensions of the PMD vector can be determined.

One The basic idea of the invention is thus to specify a polarization diversity receiver, the one complete Determining the PMD vector of an optical transmission path allows. The inventors have recognized that the relationship between the transit time difference two signals in orthogonal polarizations to determine the Components of the PMD vector can be used while so far If necessary, the transit time difference to determine the total length of a However, the direction of the vector was regularly used with the PMD vector other methods had to be determined.

Of the particular advantage of the present invention is that the Polarization controller need not be variable, but fixed are. Accordingly, the polarizers of the N are signal branches designed to rotate the polarization by a fixed predetermined value. That way you can advantageous simple components are used, in particular only static optical elements needed. Furthermore, with particular advantage no adaptive algorithm for setting the polarization controller and thus to search the PSP required.

polarization controller and polarization beam splitters depending on the embodiment be realized in separate or in a common component. Also can several components together the functionality of a polarization controller and polarization beam splitter. Accordingly are advantageous in at least one of the N signal branches of the polarization controller and the associated polarization beam splitter by a common component educated.

The Means for determining the transit time difference preferably comprise one connected to the first output of the polarization beam splitter first optoelectronic transducer and one with the second output of the polarization beam splitter connected second optoelectronic Converter, as well as one with the outputs the evaluation unit connected to the first and second optoelectronic transducers.

In a particularly preferred embodiment an inventive arrangement Accordingly, the received optical signal by means of a Power divider divided into at least three optical branches. In each of the optical branches, the signal is fixed Polarization controller led to a polarization beam splitter, the Signal components in two orthogonal polarizations in two separates separate optical signal paths, each one an optical-electrical Transducer supplied which provide a first and a second electrical signal. The from the first and second electrical signal by means of the evaluation determined transit time difference in each of the at least three optical Branches provides a component of the PMD vector, with more as three optical branches due to averaging the measurement error can be reduced.

Corresponding the above preferred methods for determining the transit time difference the evaluation unit is preferably optionally for determining the transit time difference by means of a torque formation or by means of a cross-correlation function educated.

To This purpose is advantageous in each of the N optical signal branches two delay elements provided, one of which by the respective evaluation unit controllable for tuning and accordingly via a feedback line with this is connected and one advantageous fixed. The delay element each serves to one of the two output signals of the respective To delay polarization beam splitter. By the combination with a second fixed delay can be negative achieve relative runtime differences.

The delay elements may advantageously be provided optionally as optical or electrical delay elements, for example formed as a corresponding delay line. The transit time difference is thus determined by tuning an electrical or optical delay line and determining the cross-correlation maximum at τ = 0. Electrical delay elements are preferably connected between the respective first and second optoelectronic converter and the evaluation unit, optical delay elements are preferably between the polarization beam splitter and the respec connected to the first and second optoelectronic converter.

Prefers comprises an arrangement according to the invention Furthermore, a computing unit, which is adapted to the setting the N polarization controller and determined in the N signal branches N runtime differences a value for the polarization mode dispersion, in particular the coordinates of a PMD vector.

To the Balancing the for the optical transmission path determined polarization mode dispersion, the inventive arrangement Furthermore, a compensation unit for compensating the determined Polarization mode dispersion include.

The The invention will be described below with reference to exemplary embodiments explained in more detail with the accompanying drawings.

It demonstrate:

1 : a first preferred embodiment of an arrangement according to the invention,

2 A second preferred embodiment of an arrangement according to the invention, in which electrical delay lines are provided for determining the transit time difference.

3 A third preferred embodiment of an arrangement according to the invention, in which optical delay lines are provided for determining the transit time difference,

4 A fourth preferred embodiment of an arrangement according to the invention with three signal branches, wherein polarization controller and polarization beam splitter are combined in one component.

1 shows an arrangement according to the invention 10 for measuring the PMD vector of the first order, at the input of which an affected by polarization mode dispersion optical signal S via the line 20 is fed. Through a power divider 30 the optical signal S is split into N signal paths, where N equals at least three. The optical signals in the signal paths 1-N are referred to as S1 to SN. In each of the N signal paths, the optical signal S1-SN becomes one of the polarization controllers 41 - 4N fed to the optical signal on the orthogonal main axes of one of the polarization beam splitter 51 - 5N maps. Each of the polarization plates 41 - 4N is designed differently and each fixed to a different mapping of the signals S1-SN to a signal with two orthogonally polarized signal components S1a / S1b-SNa / SNB. Each of the polarization beam splitters 51 - 5N separates the signal components S1a / S1b-SNa / SNb in the orthogonal main axes into two separate signal paths, one of which is in each case one of the first optoelectronic transducers 61a - 6Na and the other, each one of the second optoelectronic transducers 61b - 6Nb be supplied. The first optoelectronic transducers each deliver one of the electrical signals T1a-TNa, the second optoelectronic transducers respectively supply one of the electrical signals T1b-TNb. Due to the impairment of the optical signal S by polarization mode dispersion, signals of the respective signal pairs T1a / T1b - TNa / TNb have a propagation delay difference with respect to one another. The runtime difference is determined by the evaluation units 71 - 7N determined. In this exemplary embodiment, the transit time difference is determined by the evaluation unit by forming the normalized first moment of the evaluation unit associated signal of the first signals T1a-TNa and the associated signal of the second signals T1b-TNb, wherein each of the difference of the normalized first moments corresponds to the transit time difference , or by determining the position of the maximum of the cross-correlation function of the evaluation unit associated signal of the first signals T1a-T1N and the evaluation unit associated signal of the second signals T1b-TNb.

The N arms of the arrangement 10 provide N delay differences, taking into account the setting of the N polarization controller 41 - 4N be converted to the components of the three-dimensional PMD vector.

Alternatively, the delay difference can be determined by setting the maximum of the cross-correlation function at τ = 0. Two preferred embodiments of this variant of the invention are in the 2 and 3 shown.

2 shows a second arrangement according to the invention 11 for measuring the PMD vector of the first order, at its input via the line 20 In turn, a PMD impaired signal S is fed through the power divider 30 is divided into N signal paths, where N again has at least the value of three. In each of the N signal paths, the respective signal S1-SN in turn passes through one of the polarization controllers 41 - 4N that sends the signal to the main axes of one of the polarization beam splitters 51 - 5N maps.

Each of the polarization beam splitters 51 - 5N separates the signal components in the main axes into two separate signal paths, one of which is in each case one of the first optoelectronic transducers 61a - 6Na and the other, each one of the second optoelectronic transducers 61b - 6Nb be supplied.

The first optoelectronic converters 61a - 6Na provide the signals T1a-TNa, those of the respective evaluation 71 - 7N be supplied. Unlike the in 1 The illustrated embodiment of the second optoelectronic converters 61b - 6Nb supplied signals each one of the tunable electrical delay lines 81 - 8N whose outputs supply the signals T1b-TNb corresponding to the respective evaluation units 71 - 7N be supplied. The first of the opto-electronic converters 61a - 6Na supplied signals are each supplied to one of the fixed electrical delay lines 181-18N, the outputs of which deliver the signals T1a-TNa corresponding to the respective evaluation units 71 - 7N be supplied.

About the feedback lines 101 - 10N become the delay lines 81 - 8N through the corresponding evaluation units 71 - 7N tuned to obtain a maximum of the cross-correlation function of the signal pairs T1a / T1b - TNa / TNb at τ = 0 for each of the N signal branches. The settings of the delay lines 81 - 8N each provide the transit time difference between the signals of the respective signal pair. By the combination of tunable delay line 81 - 8N and fixed delay line 181 - 18N can be positive and negative values of the delay determine. The N arms of the array thus provide N skew differences taking into account the setting of the N polarization plates 41 - 4N be converted to the components of the three-dimensional PMD vector.

3 shows a third arrangement according to the invention 12 that differ from the arrangement in 2 only differentiated by the position of the delay lines.

The first of each through the polarization beam plates 51 - 5N provided signal paths in this embodiment, one of the fixed optical delay lines 191 - 19N supplied, the outputs of the delay lines 191 - 19N with the respective inputs of the first opto-electronic converter 61a - 6Na are connected. The second of each through the polarization beam splitter 51 - 5N provided signal paths in this embodiment, one of the tunable optical delay lines 91 - 9N supplied, the outputs of the delay lines 91 - 9N with the respective inputs of the second optoelectronic transducers 61b - 6Nb are connected. The delay lines 91 - 9N are in turn via feedback lines 101 - 10N through the respective evaluation units 71 - 7N tunable to obtain the respective maximum of the cross-correlation function of the signal pairs T1a / T1b - TNa / TNb at τ = 0, wherein the respective delay difference by the setting of the respective delay lines 91 - 9N results.

4 shows a fourth arrangement according to the invention 13 for determining the PMD vector of the first order, at whose input an optical signal S impaired by polarization mode dispersion via the line 20 is fed. Through a power divider 30 the optical signal S is divided into three signal branches. In the first signal branch, the optical signal 51 by means of a linear polarization beam splitter 151 split into its E _X and E _y components and in each case the optoelectronic transducers 61a respectively. 61b fed. In the second signal branch is a polarization beam splitter 152 arranged, which is aligned 45 ° to E _X. In the third signal branch is a λ / 4 plate for the S ₃ component 143 and a 45 ° downstream polarization beam splitter 153 arranged. The arrangement represents a simplification of the 1 shown arrangement 10 in which a combination of the polarization controller and polarization beam splitter is used in one component or the polarization controller is reduced to a minimum of functionality. Each of the polarization beam splitters 151 . 152 and 153 supplies in each case two signal components S1a / S1b, S2a / S2b and S3a / S3b, which respectively correspond to the optoelectronic converter pairs 161a / 161b . 162a / 162b and 163a / 163b be supplied. The outputs of the optoelectronic converters supply the electrical signal pairs T1a / T1b, T2a / T2b and T3a / T3b, which are the evaluation units 71 . 72 respectively. 73 be supplied. By means of the evaluation units 71 . 72 and 73 the transit time differences of the respective signal pairs are determined.

Claims (20)

Method for determining the first order polarization mode dispersion of a given optical transmission path, comprising the steps of - passing an optical signal through the predetermined optical transmission path, - receiving the transmitted optical signal (S), - dividing the received optical signal (S) into N partial optical signals ( S1-SN), where N is greater than or equal to three, - mapping the N partial optical signals (S1-SN) to one optical signal having two signal components (S1a / S1b-SNa / SNb) with predetermined orthogonal polarizations, - dividing the two Signal portions (S1a / S1b-SNa / SNb) having predetermined orthogonal polarizations on a first and a second optical signal for each of the N mapped partial optical signals, - determining the transit time difference between the first and second optical signals for each of the N Pairs of first and second optical signals, - Determining the polarization mode dispersion of the optical transmission path from the N predetermined images of the partial signals to orthogonally polarized signal components and the N determined transit time differences, wherein the N predetermined mappings of the partial signals to orthogonal signal components each differ from each other. The method of claim 1, wherein determining the transit time difference between the first and second optical signals comprises the steps of: converting the first optical signal (S1a-SNa) into a first electrical signal (T1a-TNa), converting the second optical signal ( S1b-SNb) into a second electrical signal (T1b-TNb), determining the transit time difference from the first (T1a-TNa) and second (T1b-TNb) electrical signal by means of an evaluation unit ( 71 - 7N ) to which the first (T1a-TNa) and second (T1b-TNb) electrical signals are supplied. Method according to one of the preceding claims, wherein Determining the transit time difference by means of a torque he follows. Method according to one of the preceding claims, wherein the determination of the transit time difference by means of a cross-correlation function he follows. The method of claim 4, wherein determining the Delay difference between the first and second optical signals the delaying of the first and / or second optical signal. The method of claim 4, wherein determining the Delay difference between the first and second optical signals the step includes: - Convert of the first optical signal (S1a-SNa) into a first electrical one Signal (T1a-TNa), - Convert of the second optical signal (S1b-SNb) into a second electrical Signal (T1b-TNb), and - delaying the first and / or second electrical signal. Method according to one of the preceding claims, wherein the mapping of the N partial optical signals (S1-SN) to orthogonal signal components by means of N fixed polarization plates ( 41 - 4N ) he follows. Method according to one of the preceding claims, wherein determining the polarization mode dispersion determining a First order PMD vector. Arrangement ( 10 - 13 ) for determining the polarization mode dispersion of the first order of a predetermined optical transmission path from an optical signal (S) which has passed through the optical transmission path, comprising - a power divider ( 30 ) with N outputs, where N is greater than or equal to three, - N signal branches, each connected to one of the N outputs of the power divider ( 30 ), each of the N signal branches comprising: - a polarization controller ( 41 - 4N ) for imaging an optical signal onto an optical signal having two signal components with predetermined orthogonal polarizations, - a polarization controller ( 41 - 4N ) associated polarization beam splitter ( 51 - 5N ) for splitting an optical signal into two optical signals having a first and a second output, - with the first and the second output of the polarization beam splitter ( 51 - 5N ) means for determining the transit time difference between a first and a second optical signal. Arrangement according to claim 9, wherein in at least one of the N signal branches the means for determining the transit time difference - one with the first output of the polarization beam splitter ( 51 - 5N ) connected first optoelectronic transducer ( 61a - 6Na ), - one with the second output of the polarization beam splitter ( 51 - 5N ) connected second optoelectronic transducer ( 61b - 6Nb ), and - an evaluation unit connected to the outputs of the first and second optoelectronic transducers ( 71 - 7N ). Arrangement according to claim 10, wherein the evaluation unit ( 71 - 7N ) is designed to determine the transit time difference by means of a torque formation. Arrangement according to claim 10, wherein the evaluation unit ( 71 - 7N ) is designed to determine the transit time difference by means of a cross-correlation function. Arrangement according to claim 12, comprising between the second optoelectronic converter ( 61b - 6Nb ) and the evaluation unit ( 71 - 7N ), tunable electrical delay element ( 81 - 8N ), which is to be reconciled via a feedback line ( 101 - 10N ) with the evaluation unit ( 71 - 7N ) connected is. Arrangement according to claim 13, comprising a between the first optoelectronic transducer ( 61a - 6Na ) and the evaluation unit ( 71 - 7N ), fixed electrical delay element ( 181 - 18N ) setting the negative delays of the tunable electrical delay lements ( 81 - 8N ). Arrangement according to Claim 12, comprising a second optoelectronic converter ( 61b - 6Nb ) upstream, tunable optical delay element ( 91 - 9N ), which is to be reconciled via a feedback line ( 101 - 10N ) with the evaluation unit ( 71 - 7N ) connected is. Arrangement according to claim 15, comprising a first optoelectronic transducer ( 61a - 6Na ) upstream, fixed optical delay element ( 191 - 19N ) adjusting the setting of negative delays of the tunable optical delay element ( 91 - 9N ). Arrangement according to one of the preceding claims, wherein in at least one of the N signal branches of the polarization controller and the associated polarization beam splitter by a common component ( 151 . 152 ) are formed. Arrangement according to one of the preceding claims, wherein the polarization controller of the N signal branches for setting only one fixed predetermined polarization are formed. Arrangement according to one of the preceding claims, further comprising an arithmetic unit, which is formed from the setting of the N polarization controller ( 41 - 4N ) and to calculate a polarization mode dispersion from N differences determined in the N signal branches. Arrangement according to claim 19, wherein the arithmetic unit is designed for calculating a PMD vector.