The invention refers to a method and an arrangement for blind demultiplexing of polarisation diversity signals for a coherent receiver.
In order to meet the growing demand for internet bandwidth with traffic growth rates around 40-50% per year, telecommunication component providers face the task of increasing the spectral efficiency of fiber utilization. After 10 Gbit/s systems (G−Giga) became successful in the 1990's, solutions for 40 Gbit/s became available in the last years. Standardization and research are now focused on the development of 100 Gbit/s systems with coherent polarisation multiplexed (CP) QPSK being the most likely modulation format for next generation systems. Since polarisation multiplexing utilizes both light polarisations, it is possible to send the signal at a rate of ˜25-28 Gsymbols per second, thus fitting nicely into the standard 50 GHz grid for DWDM (Dense Wavelength Diversity Multiplex) optical systems.
In some applications, like point-to-point radio systems, where polarisation multiplexing is employed, a visual line of sight is given, so that transmitter and receiver polarisations can be aligned during installation, and usually only small variations of the polarisation occurs.
Manually aligning the transmitter and receiver polarisations is not possible for fiber links with time-varying polarisation changes. Other solutions have been proposed for optical fiber systems like polarisation controllers. In fiber optic systems, polarisation changes arbitrarily with time and an adaptive optical polarisation controller is complicated and expensive. Moreover, PDL (polarisation depending loss) leads to a polarisation-dependent attenuation, thereby causing different SNR-levels (signal-to-noise ratio) for the two polarisations.
Since coherent reception also enables the separation of orthogonally polarized signals in the electrical domain, the use of a similar polarisation controller is not needed nor economically viable.
Current fiber network standards do not incorporate training sequences, so that in the receiver the channel has to be estimated blindly without any further knowledge.
E. g. Seb J. Savory, “Digital filters for coherent optical receivers”, Optics Express 16, No. 2, pp. 804-817, 9. January 2008 describes the principles of digital coherent receivers. Savory describes especially blind polarisation demultiplexing by multidimensional digital filtering and compensation of polarisation independent impairments by dispersion compensators and of polarisation dependent impairments by a multidimensional filter referred to as a butterfly filter.
Two algorithms are applied, the LMS (Least Mean Square) algorithm is employed after the carrier phase has been acquired, and the received symbols are compared with ideal symbols in order to derive errors for channel tracking, and the CMA (constant modulus algorithm) that is used for initial acquisition without requiring carrier phase compensation, where the goal is to achieve symbols of equal power. Applying these equalisation algorithms can lead to degenerative solutions, where one polarized signal is demultiplexed to both output polarisations and half of the information lost.
It is an object of the invention to provide a method and an arrangement for blind polarisation demultiplexing.
The object is achieved by the features recited in a claimed method and arrangement.
The present invention provides a method for blind demultiplexing of a polarisation diversity multiplex signal in a coherent receiver deriving x-polarisation samples and orthogonal y-polarisation samples of the received polarisation diversity multiplex signal, calculating complex functions of a multidimensional filter between said x-polarisation samples, y-polarisation samples and output signal x-samples, output signal y-samples representing optical signals received as polarisation diversity multiplex signal the method comprising the steps of
The present invention further provides an arrangement for blind demultiplexing of a polarisation diversity multiplex signal in a coherent receiver with a multidimensional filter receiving x-polarisation samples and y-polarisation samples of the received polarisation diversity multiplex signal and with a control unit determining complex filter functions by a standard equalisation algorithm of the multidimensional filter and outputting signal x-samples and signal y-samples representing optical signals (SH and SV) of the received polarisation diversity multiplex signal
the arrangement comprising an error calculating circuit including
Advantageous features are described in the pending claims.
Examples of the invention including a presently preferred embodiment are described below with reference to accompanying drawings, where
An embodiment of the invention will be described as a part of a coherent polarisation diversity multiplex (polmux) receiver. This system transmits two optical signals SH and SV with the same carrier wavelength but orthogonal polarisations in two subchannels of a single-carrier transmission channel.
These complex samples XI (n)+jXQ(n) and YI(n)+jYQ(n) still carry all the information of the optical component signals Sx and Sy (which usually are not the transmitted signals).
These samples are often dispersion compensated by separate dispersion compensation units 61 and 62 (CDC−chromatic dispersion compensation). Subsequently the timing phase and frequency offsets are corrected in an interpolator and clock recovery unit 7 known to those skilled in the art in order to enable fast equalizer convergence. Then these corrected filter input samples rx(n)=rXI(n)+jrXQ(n) and ry(n)=rYI(n)+jrYQ(n),—also referred to as “x-polarisation samples” and “y-polarisation samples”—are fed to a FIR (finite impulse response) butterfly equalizer 8 (implemented as filter or as digital processor with the same functionality), which reconstructs the received optical signals SH, SV in a sample format as x-signal samples zx(n)=zXI(n)+jzXQ(n) and y-signal samples zy(n)=zYI(n)+jzYQ(n) (the r and z in-phase and quadrature samples are only shown in
a shows a more detailed block diagram of the multidimensional butterfly equalizer and
The FIR filter with N=3 taps illustrated in
The proposed invention consists of an adaptation algorithm for the FIR butterfly filters that can be used on top of the standard equalisation algorithms in order to separate the two polarisations. While blind algorithms like CMA equalize for the linear channel distortion, the proposed blind source separation (BSS) approach evaluates the correlation between the two equalized signals corresponding to two polarisations and calculates error correction values to update the equalizer taps and decorrelate the two signals. The time averaged correlation between equalized x-signal samples zx[n] and y-signal samples zy[n] at time instant n is given by
ρxy(n)[k]=(1−ε)·ρxy(n−1)[k]+ε·zx[n]zy*[n−k]; k=0, . . . , kmax
ρyx(n)[k]=(1−ε)·ρyx(n−1)[k]+ε·zy[n]zx*[n−k]; k=0, . . . , kmax (1)
where ρ-correlation factor, ε is a forgetting factor ca. 0.01-0.1. zx=x-signal sample, zy=y-signal sample, zx*, zy*—conjugate complex signal values, k—correlation delay time variable, which corresponds to the time delay between the equalizer output x/y-signal samples/symbols.
Here, each polarisation is correlated with post cursors, thus effectively giving correlation for both precursors and post cursors. The number of correlation coefficients, which must be taken into account, depends on the number N of filter taps and a maximum timing offset between the two signals that shall be detected and removed. If it is guaranteed that there is no timing offset between the two signals at the output of the equalizer one tap would be sufficient.
The error correction factors ηx and ηy are given by
wherein k=0, . . . , kmax; k=correlation delay time variable;
The equalizer is updated similarly to algorithms like LMS and CMA, which are still needed for equalisation purposes. The filter coefficients hxx(n)[k], hyx(n)[k], hxy(n)[k], hyy(n)[k] at time instant n are given by
hxx(n)[k]=hxx(n−1)[k]+μ·ηy(n)·ry[n−k]+eCMA,LMS(n)
hyx(n)[k]=hyx(n−1)[k]+μ·ηx(n)·ry[n−k]+eCMA,LMS(n)
hxy(n)[k]=hxy(n−1)[k]+μ·ηy(n)·rx[n−k]+eCMA,LMS(n)
hyy(n)[k]=hyy(n−1)[k]+μ·ηx(n)·rx[n−k]+eCMA,LMS(n), (3)
where eCMA,LMS are the updates from LMS and CMA, rx, ry=equalizer filter input sample values; μ=update factor ca. 0.0001-0.01; index xy means from x to y; and
The filter functions derived by a standard algorithm are corrected by adding correction values from the second terms of these equations. It is sufficient that the two equalizer filters hyx and hxy are updated according to the invention while the other two filters are only updated according to a common algorithm.
For an implementation, the presented equations can be simplified. It is only necessary to compute the error values ηx, ηY from the maximum of both correlation factors ρxy, ρyx and the associated filter output samples zx(n), zy(n) reducing the complexity of the update algorithm and therefore the circuit complexity of a calculation circuit.
ηx(n)=−ρxy(n)[kx]·zy[n−kx] for kx=argmax{ρxy(k)}; k=0, . . . ,kmax,
ηy(n)=−ρyx(n)[ky]·zx[n−ky] for ky=argmax{ρyx(k)}; k=0, . . . ,kmax, (4)
The complexity is further reduced if only one error value η(n) is derived for both polarisations in an error calculation circuit 13 as shown in
A first storage SX1 receives and stores signal x-signal samples zX(n) and outputs time delayed x-signal samples zX(n−1) with the symbol rate 1/T. A second storage SY2 receives samples zy(n) and outputs delayed y-signal samples zy(n−1), also with the symbol rate 1/T. The number of storage stages (e.g. of a shift register) depends on the necessary correlation length and depends therefore of the number N of filter taps and filter clock rate; only one storage stage for each polarisation and k=0, 1 (N=2) is shown for reasons of clarity in this embodiment.
The correlation factors ρxy(n)[k], ρyx(n)[k] are derived according to the equations (4). Conjugate complex sample values zX*(n) are derived from actual signal y-samples zy(n) and from time shifted signal samples zy(n−1), zx(n−1) by calculation circuits CC. The conjugate complex signal samples zy*(n), zy*(n−1) are then multiplied by an actual signal x-signal sample zx(n) by multipliers M1 and M2. The time shifted signal x-signal sample zx(n−1) is converted into a conjugate complex x-signal sample zx*(n−1) and multiplied by the actual y-signal sample zy(n) by a multiplier M3. The result is multiplied by a forgetting factor ε (ca. 0.001-0.1) and added to the already stored sums in storages ST1-ST3. The sum is reduced by (1−ε) for each new sample by calculation circuits comprising storages ST1-ST3, multipliers (1−ε) and adders A1-A3. Only three calculation paths are needed for the calculation of ηx and ηy because ρxy(k=0)=ρ*yx(k=0). Multiplications by the forgetting factor ε (and by the update factor μ in the control unit 11) can be simplified and replaced by bit shifting (equivalent to the division by a power of 2 for binary numbers). Of course, other stores and calculation units may be applied.
The derived correlation factors ρyx(n)[0], ρyx(n)[1], and ρxy(n)[1] are fed to a maximum detector 13, which selects a maximum absolute correlation value and controls a second multiplexer MUX2 and a first multiplexer MUX1. Different error values ηx, ηY may be calculated with a time multiplex arrangement or with an additional multiplexer. But also the calculation of a common error values η(n) is sufficient. The correlation factor with a maximum absolute value (e.g. ρyx[1]) is fed via the multiplexer MUX2 to a multiplier M4 and the associated sample value (e.g. zY[n−1]) is fed via the first multiplexer MUX1 to the multiplier M4. The selected correlation factor is then multiplied by the associated signal sample value according to equations (2). The negative product is a simplified common error correction factor η(n), which is used instead of ηx, ηY in the equations (2) or (3) for calculating the filter coefficients. Moreover, correlation factors below a certain threshold are discarded, in order to avoid noise enhancement.
The performance can be evaluated in presence of PDL (Polarisation-Dependent Loss) against theoretical boundaries given by the attenuation inflicted by PDL. Only if the equalizer performance is on these boundaries, the equalisation can be considered optimal.
The present invention is not limited to the details of the above described principles. The scope of the invention is defined by the appended claims and all changes and modifications falling within the equivalents of the scope of the claims are therefore to be embraced by the invention.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/056532 | 5/28/2009 | WO | 00 | 11/28/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/136068 | 12/2/2010 | WO | A |
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Zhang H et al: “Polarization demultiplexing based on independent component analysis in optical coherent receivers” Optical Communication, 2008. ECOC 2008. 34th European Conference on, IEEE, Piscataway, NJ, USA, Sep. 21, 2008, pp. 1-2, XP031380905 ISBN: 978-1-4244-2227-2. |
Seb J Savory: “Digital filters for coherent optical receivers” Optics Express, OSA (Optical Society of America), Washington DC, (US), vol. 16, No. 2, Jan. 21, 2008, pp. 804-817, XP007906766 ISSN: 1094-4087. |
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20120084619 A1 | Apr 2012 | US |