DE4310254A1 - Optical reduction of non-linear optical amplitude distortion - Google Patents

Abstract

Particularly in analog optical broadband transmission (CATV), stringent requirements are imposed on the non-linearity of the optical signal. It is known for the modulation signal to be electrically pre-emphasised or for the signal received in the receiver to be electrically equalised or for distortion to be prevented through the use of components with linear characteristics. In the invention, non-linear amplitude distortion of optical signals from polarised, wavelength-modulated light is reduced in an entirely optical manner through the arrangement of a polarisation setting (birefringent) component (PS) and a double-refracting medium (DM). The signal is fed via the polarisation setting component (PS) and the double-refracting medium (DM) disposed downstream to a receiver (E). The frequency spectrum of the electrical output signal of the receiver (E) is analysed and minimised through variation of the plane of polarisation of the light in the polarisation setting component (PS). <IMAGE>

Description

The invention relates to a device for reducing non-linear Amplitude distortions of an optical signal according to the Preamble of claim 1.

Such a device is e.g. B. from the publication frequency 38 (1984) 9, pages 206 to 212 under the title "Linearization of Broadband Optical Transmission Systems by Adaptive Predistorion " known. In the known device, the electrical Modulation signal with which the optical carrier modulates in the laser is subjected to electrical predistortion in the manner that the non-linearity of the output power / laser current characteristic is compensated for as far as possible by the electrical predistortion. It it is also known that signal distortion is basically also in the electrical range of an optical receiver can be reduced can.

Such known devices are used in the optical transmission technology, especially in transmission analog signals, which place a particularly high demand on the linear transmission of the amplitude values is provided.  

For a multi-channel television system in the Federal Republic of Germany in the so-called PAL B / G format with 35 television channels and 30 VHF radio channels, e.g. B. from the network operator German Bundespost Telekom demanded a value for distortion, the Level is less than -65 dB below the level of the image carrier.

Such distortions arise mainly due to the Non-linearity of the components used in the transmission system. The linearity of the transmission is currently limited to in Laser diode used as a light source for every optical transmitter. they has a slight curvature of the output power / laser current characteristic in the working point and thereby causes a non-linearity of the second Order that after the signal conversion from the optical signal to a electrical signal in a receiver of the transmission system usually as second order distortion products (composite second Order) can be measured.

In an effort to avoid such distortions in the transmission system minimize, is the font IEEE Transactions on Microwave Theory and Technique, Vol. 38 No. 5, May 1990, pages 483-493 as a result it can be seen that satisfactory results with good lasers, i. H. with lasers that are as linear as possible at the working point P / I characteristic curve can be achieved. This linearity is technically not easy to achieve, because they are special places high demands on the laser diode.

The invention is based on the object, these undesirable Reduce nonlinearities in a technically simple way.

The object is achieved by the features of claims 1, 9 and 10 solved.

Advantageous configurations can be found in the dependent claims. Embodiments of the invention are described with reference to FIGS. 1 to 5. Show it:

Fig. 1 is a schematic illustration of an embodiment

Fig. 2 shows an embodiment with multi-stage reduction,

Fig. 3 is a discretely constructed embodiment,

Fig. 4 is a fiber optically constructed embodiment, and

Fig. 5 shows the frequency spectrum of the signal analyzed.

An exemplary embodiment of the invention is shown schematically in FIG. 1. A device V for reducing non-linearities is arranged in the transmission path A of a transmission system. The transmission path A has a directly modulated laser diode L for generating an optical, amplitude-modulated signal. The input of the laser diode L is connected to an electrical signal source S, in which the electrical modulation signal is processed. The optical output of the laser diode L is via the device V for reducing non-linear amplitude distortions with an optical receiver E, for. B. a photodiode.

The chirp effect occurs in the laser diode L when the amplitude-modulated optical signal is generated, ie, in the case of amplitude modulation, a frequency (wavelength) modulation of the optical signal which is dependent on the respective amplitude value occurs at the same time. At the same time, the optical signal experiences an undesired non-linear distortion due to the non-linear characteristic between the modulation current and the output power of the laser diode L, which ideally is completely compensated for by the device V arranged below for reducing non-linear distortions, but is only reduced in practice. Between the laser diode L and the device V, an optical signal polarizing element Pol is drawn in FIG. 1, which consists of several polarizing parts, among other things also of plug connections with oblique plug end faces, between two optical fiber optical fibers or a so-called arranged in front of the laser output Brewster window can be formed.

In the simplest case there is a polarization controller PS and a birefringent medium DM in the device V for reducing non-linear amplitude distortions. The birefringent medium DM has two different refractive indices n ₀ and n _a0 transversely to the direction of propagation, viewed orthogonally, which lead to this propagating light for different polarization states also has different optical path lengths. Appropriate adjustment of the polarization direction of the light in the polarization controller PS changes the polarization transformation properties and thus enables the adjustment of the nonlinear distortion to a minimum value.

Since for a real transmission path between laser diode L and receiver E, with all components used, the optimal setting of the polarization controller PS cannot theoretically be detected, e.g. B. because of polarization rotations in the optical amplifier, splice connections, fiber-optic cables used with all bends and curvatures that such a waveguide experiences, the setting of the polarization controller PS is carried out by analyzing the frequency spectrum of the electrical signal obtained from the receiver E. With this setting method, nonlinear distortions with which the transmission signal is afflicted can be reduced to a minimum, regardless of the origin of the distortion. Such a frequency spectrum is shown in FIG. 5. FIG. 5 shows the normalized amplitude of a spectrum with second-order distortions plotted against the frequency. The image carrier (signal) is at 48.250 MHz, the two interference signals (CSO) generated by second-order distortions at f = 48.0 MHz and f = 49.0 MHz. The two interference signals caused by distortions show amplitude values that are greater than the threshold value SW = -65 dB shown, ie their level is less than -65 dB below the value of the image carrier. By suitable adjustment of the polarization adjuster PS, the interference signals caused by second-order clang can be changed and thus also minimized. To analyze the frequency spectrum can be used as a spectrum analyzer z. B. the analyzer from Anritsu with the designation MS611A can be used. The spectrum analyzer can be removed after minimizing the distortion.

To optimize the reduction of non-linear Amplitude distortions can also use several polarization adjusters PS and / or alternating multiple birefringent media, can be switched in series with regard to signal propagation.

In FIG. 2, a plurality, typically available in an optical transmission system, Pol polarizing elements are exemplary depicted schematically. A laser diode L generating the optical signal has an exit surface BF inclined by the Brewster angle. Even without an inclined exit surface BF, a laser diode generally generates light with a preferred polarization direction. As a rule, a laser diode can therefore already be considered as a polarizing element pole. The laser diode L is followed by a first device V ₁ for reducing non-linear distortions. Optical splice connections can then be located at several points in the optical transmission path, in which the fiber end faces are spliced at an angle. The splice connection K is followed by a second device V ₂ for reducing non-linear distortions. The following receiver E usually has a low-reflection optical fiber-diode coupling to avoid multiple reflections. Here, the end of the optical waveguide is broken at an angle and tilted towards the diode light entry surface. This coupling also shows a polarizing effect.

A first exemplary embodiment for the construction of a device V for reducing non-linear distortions is shown in FIG. 3. The polarized nonlinearly distorted light is guided via a fiber-optic fiber F ₁ to an imaging optic in the form of a converging lens L ₁ and then to one or more birefringent crystals PS. In a further imaging optics such. B. a second lens L ₂ , the light is bundled into the core of a second fiber optic fiber F ₂ . Due to the usually small core diameter of the first fiber optic waveguide F ₁ , the light emerges from the fiber optic waveguide F _{1 in a} highly divergent manner and is thereby parallelized by the first lens L ₁ . The polarization controller PS and one or more birefringent crystals are arranged as the birefringent medium DM between the first lens L ₁ and the second lens L ₂ . The birefringent medium DM is preferably dimensioned such that the light passing through z. B. experiences a polarization dispersion of 20 ps, ie the transit time difference of the two polarizations is 20 ps in the birefringent medium DM. Depending on the state of the light, the polarization dispersion can be changed by adding or removing birefringent crystals. It can also birefringent media DM with z. B. refractive indices which can be influenced electrically or magnetically. On the second lens L ₂ z. B. be dispensed with if the birefringent medium DM due to its shape, z. B. a prism acts as imaging optics.

FIG. 4 shows a second exemplary embodiment of a device V for reducing non-linear distortions. The device V consists of a fiber optic polarization controller PS, as z. B. from Electronics Letters, September 25, 1980, Vol. 16 No. 20, pages 778-780, and a birefringent fiber waveguide DF as a birefringent medium. A polarization dispersion of 20 ps can, for. B. can be achieved by a polarization-maintaining fiber waveguide with a length of 5 m. A birefringent medium can also be a fiber waveguide intended for other purposes, e.g. B. the fiber waveguide of a fiber amplifier can be used because the fiber waveguides are usually wound up as a coil and therefore act slightly birefringent.

Claims (10)

1. Device for reducing non-linear amplitude distortions of an amplitude-modulated optical signal, characterized in that the carrier is polarized, the carrier frequency is dependent on the amplitude values and means for optically reducing the non-linear amplitude distortions are available, taking advantage of this dependence. 2. Device according to claim 1, characterized in that it at least one element (pole) polarizing the optical signal, at least one polarization controller (PS) and at least one optically birefringent element (DM) contains that at least one birefringent element (DM) at least one polarization controller (PS) and this polarization controller (PS) or this At least one polarizing element (pole) is prefixed and that the nonlinear distortions by suitable setting of the polarization controller (PS) at least are partially compensable.   3. Device according to claim 2, characterized in that the birefringent medium (DM) a birefringent Is fiber-optic and at least part of the optical Represents transmission path. 4. The device according to claim 2, characterized in that the birefringent medium (DM) Fiber waveguide of an optical fiber amplifier is. 5. The device according to claim .2, characterized in that the birefringent medium (DM) is birefringent crystal. 6. The device according to claim 5, characterized in that the optical signal at least the light is partially guided in a fiber-optic cable expanded into a beam and the birefringent crystal in the widened beam path are arranged. 7. The device according to claim 2, characterized in that several polarization controllers (PS) and several birefringent Media (DM) are alternately connected in series. 8. Optical transmitter with a device according to claim 1, characterized characterized in that it directly modulated as a signal source Has laser diode (L).   9. Optical transmission system with a device according to claim 1, characterized in that there are several in the subscriber area Optical receiver (E) and at least in one optical receiver a device (V) for reduction nonlinear distortion is arranged. 10. Procedure for reducing the non-linear Amplitude distortion of an optical signal with a device according to claim 1, characterized in that the optical signal is optically-electrically converted, the nonlinear distortions be measured and the direction of polarization of the Polarization controller (PS) is varied until the nonlinear distortions are minimal.