EP1527537A1 - Method for transmitting at least one first and second data signal in polarization multiplex in an optical transmission system - Google Patents

Abstract

The invention relates to a method for transmitting at least one first and second data signal (ds1, ds2) in polarization multiplex. To this end, the invention provides that, in a first step, the first data signal (ds1) is, on the transmit side, modulated to a sideband (SB1) of a first carrier signal (ts) for generating a first sideband-modulated signal (ms1), and the second data signal (ds2) is modulated to a sideband (SB2) of a second carrier signal (ts) in order to generate a second sideband-modulated signal (ms2). In a second step, the first and second sideband-modulated signal (ms1, ms2) are subsequently polarized orthogonal to one another, combined to form an optical multiplex signal (oms) and transmitted. In a third step, the optical multiplex signal (oms) is, on the receive side, guided via a polarization control element (PTF) to a polarization splitter (PBS) that separates the transmitted optical multiplex signal (oms) into the first and second sideband-modulated signal (ms1, ms2). In a fourth step, the first sideband-modulated signal (ms1) is converted into a first electrical signal (es1) and/or the second sideband-modulated signals (ms2) are/is converted into a second electrical signal (es2). In a fifth step, the first and/or second electrical signal (es1, es2) are/is evaluated and at least one control signal (rs) for controlling the polarization control element (PFT) is derived on the basis of this evaluation.

Description

description

Method for transmitting at least one first and second data signal in polarization multiplex in an optical transmission system

In optical transmission systems, an expansion of the transmission capacity of existing optical transmission systems is made possible by the fact that the optical data signals are transmitted in polarization multiplex. To transmit optical data signals in polarization multiplex, two carrier signals are generated in at least one transmitter arrangement with the same wavelength, which are each modulated with a data signal. The first and second modulated signals have an orthogonal polarization. The mutually orthogonally polarized modulated signals are combined to form an optical polarization multiplex signal. The optical polarization multiplex signal is coupled into the optical transmission fiber and transmitted to a receiving unit via the optical transmission path. On the reception side, the two orthogonally polarized modulated signals are recovered from the polarization multiplex signal depending on the wavelength and polarization.

The recovery of the two orthogonally polarized modulated signals from the polarization multiplex signal represents one of the problems in the transmission of optical data signals in polarization multiplex. For this purpose, it is necessary to determine a control criterion from the transmitted optical polarization multiplex signal for regulating a polarization control element arranged at the receiving end. With the help of the polarization actuator controlled on the basis of the appropriate control criterion and for example a subsequent polarization splitter or a polarization filter The mutually orthogonally polarized transmitted modulated signals are separated.

Different control criteria are known for controlling the separation of the two orthogonally polarized signals at the receiving end. From the publication “Optical Polarization division multiplexing at 4GB / S ^M , by Paul M. Hill et al., IEEE Photonics Technology Letters, Vol. 4, No. 5, May 1992, the use of coherent techniques in combination with pilot tones for the reconstruction or separation of the polarization-multiplexed optical signals is known. Furthermore, the publication "Fast Automatic Polarization Control System", Heismann and Whalen, IEEE Photonics Technology Letters, Vol. 4, No. 5, May 1992 separated the polarization-multiplexed optical data signals on the basis of one from the recovered clock and the optical signals received In addition, from German patent application 10147892.5 a frequency offset method for the reception-side separation of polarization-multiplexed optical data signals is known, in which two carrier signals having a differential frequency are used on the transmission side for transmission of the two data signals and the spectrum of the reception-side separation of the two data signals transmitted data signals at the differential frequency for controlling a polarization actuator is evaluated.

In addition, from the publication by Mike Sieben, et al., "Optical Single Sideband Transmission at 10 Gb / s Using Only Electrical Dispersion Compensation", Journal of

Lightwave Technology, Vol. 17, No. 10, October 1999, a method of "single sideband ^'" transmission of optical signals, in which the transmission side using at least one Mach-Zehnder modulator of a digital baseband signal using a Hilbert transform an optical unilateral generated tenbandsignal. By Transfer in only one sideband becomes the nonlinear effect of the chromatic Fiber dispersion reduced and the optical transmission bandwidth increased.

The object of the invention is to be seen in specifying a novel method for the transmission of high bit rate optical signals in polarization multiplex with increased transmission bandwidth.

The object is achieved on the basis of a method according to patent claim 1.

The main advantage of the method according to the invention can be seen in the fact that, in order to transmit at least a first and a second data signal in polarization multiplexing in an optical transmission system, the first data signal is transmitted to a sideband of a first carrier signal in a first step to generate a first sideband modulated Signal and the second .Data signal is modulated onto a sideband of a second carrier signal to generate a second sideband-modulated signal. In a second

Step, the first and second sideband-modulated signals are polarized orthogonally to one another and combined and transmitted to form an optical multiplex signal. In a third step, the optical multiplex signal is passed on the receiving side via a polarization actuator to a polarization splitter which separates the transmitted optical multiplex signal into the first and second modulated signals. Furthermore, in a fourth step, the first sideband-modulated signal is converted into a first electrical signal and / or the second sideband-modulated signal into a second electrical signal, and in a fifth step the first and / or the second electrical signal is evaluated and, depending on this, at least one control signal Regulation of the polarization actuator derived. The method according to the invention advantageously enables the transmission of data signals with a high spectral efficiency. Through the combination of the single-sided Ten-band or residual sideband modulation and optical polarization multiplex technology advantageously result in increased tolerance ranges for the optical transmission system with respect to nonlinear effects, for example the chromatic fiber dispersion.

Two carrier signals differing by a difference frequency are advantageously used for the transmission of the two optical data signals. To evaluate the first and / or the second electrical signal, the spectral component of the first and / or the second electrical signal at the differential frequency is determined on the transmission side. For the exact separation of the first and second sideband-modulated signals at the receiving end, at least one polarization actuator arranged at the receiving end is controlled, the squaring property of an opto-electrical converter, for example a photodiode, being used to obtain a control criterion. These squaring properties result in the electrical spectrum of the opto-electrical output

Transmitted electrical signal at the differential frequency undesirable spectral components, provided that the separation carried out with the aid of the polarization splitter of the two sideband-modulated signals transmitted in the polarization multiplex is not exact. These spectral components lying at the difference frequency arise in both the first and the second electrical signal. The amplitude of these spectral components is evaluated to form at least one control signal for controlling the polarization actuator. Here, the polarization actuator is used, for example

Controlled with the aid of the at least one control signal in such a way that the spectral component which arises at the differential frequency becomes minimal. With the aid of such a sharp control criterion, a separation of the two sideband-modulated signals transmitted in the polarization multiplex that is as exact as possible is possible at the receiving end. The first or second sideband-modulated signal is advantageously delayed on the transmission side, as a result of which an effective decorrelation of the first and second sideband-modulated signal is achieved. This further increases the sharpness of the control criterion.

Another advantage of the invention is the fact that at least one pilot tone signal is superimposed on the transmission side of the first and / or the second carrier signal to distinguish the first and second electrical signals. As an alternative, a pilot tone with a fixed frequency is advantageously superimposed on the first and / or second sideband-modulated signal, on the basis of which, after the transmission-side separation of the first and second sideband-modulated signals with the aid of the polarization splitter and the conversion into a first and second electrical signal, a clear identification of the first and second electrical signal as such is possible. Alternatively, to distinguish the first and second electrical signals, the first and second data signals can be transmitted with different transmission bit rates or data formats. In a further alternative embodiment, the first and second data signals have different transmission bit rates, and thus the respective electrical signal can advantageously be identified on the receiving side using the assigned transmission bit rate.

Additional advantageous embodiments of the method according to the invention can be found in the further claims.

Exemplary embodiments of the method according to the invention and of the optical transmission system according to the invention are explained in more detail below on the basis of a basic circuit diagram and several diagrams.

Figure 1 shows an example of an optical transmission system for transmitting at least one first and second data signal modulated on a sideband of carrier signals in polarization multiplex,

FIGS. 2a-d show the power spectra of the first and second sideband-modulated signals, and

FIG. 3 shows the amplitude profile of the determined spectral component at the difference frequency as a function of the polarization angle.

In Figure 1, an optical transmission system OTS is shown schematically by way of example, which has a transmission arrangement SA and a reception arrangement EA connected via an optical transmission aser OF. The transmission arrangement SA includes, for example, first and second data units D1, D2, an optical signal generation unit OSU, an optical splitter unit SU, first and second modulator units MU1, MU2, first and second optical sideband filter units 0SBF1, OSBF2, a polarization controller PC and a Polarization multiplexer PM provided. The receiving arrangement EA comprises a polarization actuator PTF, a polarization splitter PBS, a first and second opto-electrical converter RX1, RX2, a first and second filter unit FU1, FU2 and a control unit CU. The control unit CU additionally has a measuring and evaluation unit MBU.

The first data unit D1 of the transmission arrangement SA is connected to the first modulator unit MU1, which is connected to the first input il of the polarization multiplexer PM via the first optical sideband filter unit 0SBF1 and the polarization controller PC. The second data unit D2 is connected to the second modulator unit MU2, which is connected via the second optical sideband filter unit 0SBF2 and optionally via a delay element D to the second input e2 of the polarization multiplexer PM. The option of the delay element D is indicated in FIG. 1 by a dashed line. Furthermore optionally a first and a second electrical sideband filter unit ESBF1, ESBF2 are provided, which are connected between the first data unit D1 and the first multiplexer MU1 or between the second data unit D2 and the second multiplexer MU2. Either the first and second electrical sideband filter units ESBF1, ESBF2 or the first and second optical sideband filter units OSBF1, OSBF2 can be used to generate the electrical or optical sideband signals.

The optical signal generation unit OSU is connected to the first and second modulator units MU1, MU2 via the optical splitter unit SU, which has a division ratio of 1: 2, for example.

The optical transmission fiber OF is connected to the output e of the polarization multiplexer PM, the output of which is led to the input i of the polarization actuator PTF of the receiving arrangement EA. In this case, the optical transmission fiber OF can comprise a plurality of optical transmission fiber sections (not shown in FIG. 1).

The output e of the polarization actuator PTF is connected to the input i of the polarization splitter PBS. Its first output is el with the first opto-electrical

Converter RX1 and its second output connected to the second opto-electrical converter RX2. The first and second opto-electrical converters RX1, RX2 are connected to the first and second filter units FU1, FU2. The first filter unit FU1 and the second filter unit FU2 are connected, for example, via a first or a second control line RL1, RL2 to the first or second input il, i2 of the control unit CU, the output e of which via a control line SL to the control input ri des Polarization actuator PTF is connected. To evaluate the received electrical signals, the control unit CU has, for example, a measuring and evaluation unit MBU. An optical signal os is generated in the optical signal generation unit OSU, the optical signal being configured as an optical “white light signal” or an optical pulse signal that has a constant frequency. The optical signal os is transmitted to the optical splitter unit SU and divided into a first and a second carrier signal tsl, ts2. The first and second carrier signals tsl, ts2 have the same frequency fi, f ₂ . Alternatively, two separate optical signal generating units 0SU1,2 - in Figure 1 not shown - is provided, with the aid of a first and second carrier signal TSL are generated ts2, the fι a shifted by a difference frequency .DELTA.f first and second frequency, f ₂ have. The first carrier signal tsl is transmitted to the first modulator unit MU1 and the second carrier signal ts2 to the second modulator unit MU2.

In the first data unit D1, a first data signal dsl in a first data format - for example in the return-to-

Zero data format (RZ) - generated, which is led from the first data unit Dl to the first modulator unit MU1. By the first modulator unit MU1, the first data signal is dsl modulated tsl on a sideband of the first carrier signal, and ^'thereby generating a first sideband modulated signal msl, which via the first optical sideband filter unit 0SBF1 and the polarization controller PC to the first input il of the polarization PM is controlled.

Analogously to this, a second data signal ds2 is likewise generated in the second data unit D2 in the first data format or in a second data format - for example the non-return-to-zero data format (NRZ) - and transmitted from the second data unit D2 to the second modulator unit MU2 , In the second modulator unit MU2, the second data signal ds2 is modulated onto a sideband of the second carrier signal ts2. and a second sideband-modulated signal ms2 is formed, which is routed via the second optical sideband filter unit 0SBF1 and optionally via the delay element D to the second input i2 of the polarization multiplexer PM.

The first and second carrier signals tsl, ts2 can be modulated with the first and second data signals dsl, ds2 using single sideband modulation or residual sideband modulation. The transmission characteristics of the first and second electrical sideband filter units ESBF1, ESBF2 and the first and second optical sideband filter units OSBF1, OSBF2 are adapted to the respective sideband modulation method used. The first and second electrical sideband filter units ESBF1, ESBF2 and the first and second optical sideband filter units OSBFl, OSBF2 are used to filter out the sideband required for the transmission of the first and second data signals dsl, ds2 before or after the modulation, the sideband modulation is implemented, for example, with the aid of a Hilbert transformer - see the publication by Mike Sieben, et al., "Optical Single Sideband Transmission at 10 Gb / s Using Only Electrical Dispersion Compensation", Journal of Lightwave Technology, Vol. 17 , No. 10, October 1999.

When the first and second sideband-modulated signals ms1, ms2 are generated, their polarization is preset in such a way that they are polarized orthogonally to one another and thus can be transmitted in polarization multiplex via the optical transmission fiber OF to the receiving arrangement EA. For the orthogonalization of the polarization of the first and second modulated signals ms1, ms2, for example, polarization controllers PC can be provided on the receiving side. If the first and second carrier signals tsl, ts2 are generated by two separate optical signal generation units OSU, a polarization controller PC is not absolutely necessary. lent, since with the help of modern optical signal generation units OSU optical signals with a predetermined polarization can already be generated.

In the exemplary embodiment, the polarization controller PC ensures an orthogonal polarization ratio between the first and second sideband-modulated signals ms1, ms2, alternatively or additionally, a polarization controller PC can be arranged between the second optical sideband filter unit OSFB2 and the polarization multiplexer. The second sideband-modulated signal ms2 is optionally delayed by the delay element D, as a result of which the first and second sideband-modulated signals ms1, ms2 can be decorrelated on the transmission side.

The first and second sideband-modulated signals msl, ms2 are combined with the aid of the polarization multiplexer PM to form an optical multiplex signal oms, which is fed into the optical transmission fiber OF at the output e of the polarization multiplexer PM. The first and second sideband-modulated signals ms1, ms2 are then transmitted in the form of the optical multiplex signal oms in polarization multiplex via the optical transmission fiber OF.

In the receiving arrangement EA, the optical multiplex signal oms is led to the input i of the polarization control element PTF, with the aid of which the polarization of the transmitted first and / or second sideband-modulated signal ms1, ms2 can be regulated within the optical multiplex signal oms. After the polarization of the transmitted first and / or second modulated signal ms1, ms2 within the optical multiplex signal oms has been set, the optical multiplex signal oms is passed to the input i of the polarization splitter PBS, which converts the optical multiplex signal oms into the first sideband-modulated signal msl * and the second sideband-modulated signal ms2 * splits. The accuracy of the splitting of the optical multiplex signal oms into that The first sideband-modulated signal and the second sideband-modulated signal msl *, ms2 * depend on the orthogonality of the polarization of the two signals msl *, ms2 *.

The first sideband-modulated signal msl * is output at the first output el of the polarization splitter PSB and is controlled at the first opto-electrical converter RX1. Analogously to this, the second sideband-modulated signal ms2 * is emitted at the second output e2 of the polarization splitter PBS and transmitted to the second opto-electrical converter RX2.

The recovered first and second sideband-modulated signals ms1 *, ms2 * are converted by the first and second opto-electrical converters RX1, RX2 into first and second electrical signals es1, es2, which are sent to the first and second filter units FU1 , FU2 is controlled.

With the help of the first and second filter units FU1, FU2, a selected spectral component of the first and second electrical signals es1, es2 is filtered out and the filtered first and second electrical signals es1 _F , es2 _F via the first and second control lines RL1, RL2 the control unit CU transmitted.

In the control unit CU, the amplitude of the filtered first and / or the second electrical signal es1 _F , es2 _{F is} determined with the aid of the measuring and evaluation unit MBU and the amplitude / s is then evaluated. Based on the evaluation result, at least one control signal rs for regulating the polarization actuator PTF is derived, which is fed via the control line SL to the control input ri of the polarization actuator PTF. To form the control signal rs, for example the voltage amplitude or the current amplitude or the power amplitude of the filtered first and / or the second electrical signal es1 _F , es2 _F can be measured and evaluated. Here, the polarization actuator PTF controlled by the control signal rs the polarization of the optical multiplex signal oms changes in such a way that the amplitude of the filtered first and / or the second electrical signal es1 _F , es2 _F determined by the measurement and evaluation unit MBU of the control unit CU becomes minimal. This means that the receiving arrangement EA consisting of the polarization actuator PTF and the polarization splitter PBS is set optimally for separating the first sideband-modulated signal ms1 and the second sideband-modulated signal ms2.

The polarization actuator PTF can be regulated in various ways, for example by means of a pilot method, correlation method and interference method. Control according to the frequency offset method is particularly preferred (see the teaching of German patent application 10147892.5). In such a control, the first and second carrier signals tsl, ts2, the first and second sideband-modulated signals msl, ms2 have a difference frequency Δf. Due to the squaring properties of the first and second opto-electrical converters RX1, RX2, a spectral component is generated at the difference frequency Δf. With optimum setting of the polarization control element PTF these spectral components of the first and second electrical signals comprise esl, es2 a minimum on or are ^"no longer measurable. Thus, the first through the first and second filter unit FU1, FU2 this relevant spectral component at the difference frequency .DELTA.f and second electrical signal esl, es2 and the amplitude and measurement unit MBU determine the amplitude of the filtered first and / or second electrical signal esl _F , es2 _F. For this purpose, the first and second filter units FU1, FU2 are, for example, bandpass filters with a the center frequency f _M corresponding to the difference frequency Δf (for example fM = 10 GHz in the exemplary embodiment under consideration) and a bandwidth of for example 1 GHz around the difference frequency Δf. Typical values for the difference frequency Δf des first and second carrier signals tsl, ts2 are in the range greater than one gigahertz.

The arrangement shown in FIG. 1 thus realizes an exact reception-side separation of the first and second sideband-modulated signals ms1, ms2, which are polarized orthogonally with respect to one another.

In FIGS. 2a to 2d, the power spectra or distributions PSD of the first and second optical sideband-modulated signals ms1, ms2 are plotted against the frequency f in several diagrams. This is shown by way of example for the transmission of two optical data signals ds1, ds2 present in the NRZ data format using the single-sideband modulation method with a transmission rate of 10 Gbit / s each. The first optical sideband-modulated signal ms1 is indicated by a solid line and the second optical sideband-modulated signal ms2 is indicated by a dotted line.

FIG. 2a shows an example of the power distribution PSD over the frequency f for a first and second sideband-modulated signal msl, ms2, the first and second carrier signals tsl, ts2 of which have the same frequency f _τ = fι = f ₂ . Furthermore, two single-sidebands that are mirror-symmetrical to one another are selected to transmit the first and second data signals ds1, ds2.

In FIG. 2b, the first and second sideband-modulated signals msl, ms2 likewise have first and second carrier signals tsl, ts2 with the same frequency the first and data signals dsl, dsl are modulated onto the identical single sideband.

FIG. 2c shows the power distribution PSD of the first and second optical sideband-modulated signals ms1, ms2 over the frequency f in the event of a shift in the frequencies of the first and second carrier signals tsl, ts2 by a difference frequency Δf and FIG. 2d shows the resulting spectrum for the application shown in FIG. 2c.

FIG. 3 shows the amplitude curve AV on a logarithmic scale [dB] of the determined spectral component, for example the power amplitude of the filtered first and / or electrical signal esl _F , es2 _F , when there is a difference frequency Δf = 10 GHz of the two carrier signals tsl, ts2 in Dependence of the polarization angle pa is shown in a diagram. The polarization angle pa is plotted on the abscissa and the amplitude P on the ordinate. The amplitude curve AV has a maximum MAX at a polarization angle of pa = 45 °, that is to say with a polarization shift between the first and second electrical signals es1, es2 of 45 °, which at the difference frequency Δf due to the squaring property of the first and / or second opto-electrical converter RX1, RX2 caused spectral component a maximum MAX. This maximum MAX of the spectral component at the difference frequency Δf decreases with increasing as well as with decreasing polarization shift between the first and second electrical signals es1, es2 and reaches a first minimum MINχ at 0 ° and a second minimum MIN ₂ at 90 °. In the first and second minimum MINi, MIN ₂ , the first and second sideband-modulated signals ms1, ms2 transmitted within the optical modulation signal oms are ideally orthogonally polarized and can therefore be separated almost perfectly using the polarization splitter PBS. Here, when the first minimum MINi occurs at a polarization angle of pa = 0 °, the modulated signal of one polarization, for example the first modulated signal msl, and when the second minimum MIN _{2 occurs} at a polarization angle of pa = 90 °, the modulated signal is other polarization, for example the second modulated signal ms2, is detected perfectly. All other polarization angles pa are not desirable and lead to crosstalk when the first and second modulated signals ms1, ms2 are separated.

As a result of the delay, for example of the second sideband-modulated signal ms2, which is carried out with the aid of the delay element D optionally provided in the transmission arrangement SA, the control criterion shown in FIG. 3 becomes even more high-contrast, as a result of which an even sharper control signal rs can be formed in the control unit CU. For this purpose, the first or the second sideband-modulated signal ms1, ms2 can be delayed with the help of one or more delay elements D.

In addition, both the first and / or the second filtered electrical signal es1 _F , es2 _F can be evaluated to form at least one control signal rs.

In addition, additional filtering of the first and second electrical signals es1, es2 is possible at further frequencies in addition to the difference frequency Δf with the aid of the first and second filter units FU1, FU2 or further filter units, in order to thereby provide further information about the polarization of the first and second electrical signals Signals esl to get es2. This further information can then be further processed to increase the contrast of the at least one control signal rs.

In order to distinguish between the first and second electrical signals es1, es2 separated with the aid of the polarization splitter PBS, the first and second data signals ds1, ds2 can be transmitted at different transmission bit rates or, alternatively, the first and / or the second carrier signal tsl can be transmitted on the transmission side , ts2 or the first and second modulated signal msl, ms2 at least one pilot tone signal. Here, either by determining the transmission bit rate of the respective electrical signal es1, es2 at the receiving end or by the receiving Soapy identification of the pilot tone signal identifies the first and second electrical signals es1, es2 as such and can then be further processed in a signal-specific manner.

In addition, it is possible to distinguish between the first and second electrical signals es1, es2, which are separated with the aid of the polarization splitter PBS, by using different transmission bit rates for the first and second data signals dsl, ds2. Alternatively, the first and second data signals dsl, ds2 can also be transmitted in different data formats, for example RZ and NRZ, for differentiation purposes at the receiving end.

Wavelength division multiplexing technologies can be used to further increase the bandwidth efficiency of the OTS optical transmission system.

Claims

claims

1. Method for transmitting at least one first and second data signal (dsl, ds2) in polarization multiplex in an optical transmission system (OTS),

- In which in a first step the first data signal (dsl) on a side band (SB1) of a first carrier signal (ts) for generating a first sideband-modulated signal (msl) and the second data signal (ds2) on a side band (SB2) of a second Carrier signal (ts) for

Generation of a second sideband-modulated signal (ms2) is modulated,

in which, in a second step, the first and second sideband-modulated signals (msl, ms2) are polarized orthogonally to one another and combined and transmitted to form an optical multiplex signal (oms),

- In which, in a third step, the optical multiplex signal (oms) is routed via a polarization actuator (PTF) to a polarization splitter (PBS), which separates the transmitted optical multiplex signal (oms) into the first and second modulated signals (msl, ms2) .

in which in a fourth step the first sideband-modulated signal (msl) is converted into a first electrical signal (esl) and / or the second sideband-modulated signal (ms2) is converted into a second electrical signal (es2),

- In which the first and / or the second electrical signal (es1, es2) is evaluated in a fifth step and at least one control signal (rs) for regulating the polarization control element (PTF) is derived therefrom.

2. The method of claim 1, d a d u r c h g e k e n n z e i c h n e t that the sideband modulation is designed as a single sideband modulation or as a residual sideband modulation.

3. The method according to claim 1 or 2, characterized in that in the case of a second carrier signal (ts2) differing from the first carrier signal (tsl) by a difference frequency (Δf) for evaluating the first and / or the second electrical signal (esl, es2), the spectral component of the first and / or the second electrical Signal (esl, es2) is determined at the difference frequency (Δf).

4. The method according to claim 3, characterized in that the amplitude (P) of the first and / or the second electrical signal (esl, es2) at the dif ferential frequency (Δf) is regulated to a minimum (MINι, MlN ₂ ).

5. The method of claim 3 or 4, d a d u r c h g e k e n n z e i c h n e t that a value greater than one gigahertz is selected as the difference frequency (Δf).

6. The method according to any one of claims 1 to 5, so that the first or second sideband-modulated signal (msl, ms2) is delayed on the transmission side for decorrelation.

7. The method according to any one of claims 1 to 6, characterized in that to distinguish the first and second electrical signals (esl, es2) on the transmission side, the first and / or the second carrier signal (tsl, ts2) or sideband-modulated signal (msl, ms2) at least a pilot tone signal is superimposed.

8. The method according to any one of claims 1 to 6, characterized in that to distinguish the first and second electrical signals (esl, es2), the first and the second data signal (dsl, ds2) are transmitted with different transmission bit rates. ^•

9. The method according to any one of claims 1 to 6, so that the first and second data signals (esl, es2) are transmitted in different data formats in order to distinguish the first and second electrical signals (esl, es2).

10. The method according to any one of claims 1 to 9, so that the optical transmission system (OTS) is operated in wavelength multiplexing (WDM).