DE102014000655A1 - Method and arrangement for transmitting information by means of linearly polarized electromagnetic waves - Google Patents

Abstract

Method and arrangement for transmitting useful signal information (eg speech, music, data) by means of differently linearly polarized electromagnetic waves as information carrier. The linearly polarized electromagnetic waves each have a different predeterminable polarization angle phi. Each linearly polarized wave is derived from another source electromagnetic wave. On each of the linearly polarized waves a signal to be transmitted by modulation useful signal information is impressed. On the receiving side, there is a polarization-angle-specific separation of the modulated linearly polarized electromagnetic waves and their demodulation.

Description

The invention relates to a useful signal information transmission by means of linearly polarized electromagnetic waves, preferably by means of linearly polarized laser beams. From the dissertation "Arrival Time Detection for Polarization Mode Dispersion in Optical Transmission" by Vitaly MIRVODA; University of Paderborn, 2009; Entry of the German National Library Frankfurt am Main, http://d-nb.info/992775345) and from the German patents (derived from the inventor Dr.-Ing. Reinhold Noe) DE 102 16 281 . DE 103 34 154 . DE 198 46 573 It is known, inter alia, to use two differently linearly polarized laser beams for information transmission, which are generated by birefringence from a single laser beam. Birefringence (which uses birefringent materials such as lithium niobate) always splits a single beam into exactly two beams. The differential refraction results in different velocities of the refracted rays within the birefringent material. This results in a phase shift between the refracted beams, which depends on the material thickness of the birefringent material. It takes a high technical equipment effort to compensate for or reduce this due to birefringence disadvantage. It is an object of the invention to provide a method for transmitting information by means of linearly polarized electromagnetic waves, which allows with simple means the simultaneous transmission of a plurality of (even more than two) modulated different linearly polarized waves. It is a further object of the invention to provide an arrangement for carrying out the method according to the invention.

This object of the invention is achieved by the features specified in the characterizing part of claim 1 and 3 respectively. Advantageous developments of the invention are characterized in the subclaims. The differently linearly polarized electromagnetic waves act as carriers for different useful signals (eg speech, music, data) with which the waves are modulated. In other words, each carrier transmits another "program". However, the carriers may not have the same fundamental frequency. For equal-frequency modulated carriers there is basically no bandwidth increase, but it does occur when using carriers with different fundamental frequencies. For the receiver-side distinction of the carrier is not the frequency, but the polarization angle prevail. The invention relates to the entire field of electromagnetic waves. For realizing the invention u. a. semi-transparent mirrors and polarizing filters needed. Such have been available as merchandise only for the wavelength range of visible light and for the ultraviolet range. Linear polarizing filters are linear polarizing optical filters; they are z. B. by the company Erwin Käsemann GmbH in Oberaudorf / Germany am Inn distributed. A polarizing filter consists of a polaroid with linearly arranged macromolecular molecules. The macromolecules can be twisted together to set a desired polarization angle. Diffused Halogne (iodine, chlorine, bromine or fluorine) make the macromolecules optically active. The linear alignment is achieved by stretching the material. The stretching direction coincides with the polarization direction. Furthermore, there are other possibilities for the realization of polarizing filters, eg. Example by Nicolscher prisms or trigononal crystals. The function of the invention is independent of the type of polarizing filter.

For electromagnetic waves outside of this wavelength range (of the visible light and ultraviolet range), however, it would be possible to develop and manufacture such polarizing filters, etc., but costs and possibly dimensional reasons advise z. At the moment still off.

Optical fibers are components, in particular transparent fibers, rods or tubes that transport light. The most important optical fibers in communications technology are the so-called optical waveguides, in which the light transport based on the wave properties of light. Such optical fibers are usually made of glass fibers (hence the name fiber optic cable or fiber optic cable). The best known form of optical fibers are the so-called fiber optic cables. Optical waveguides are physically dielectric waveguides with which electromagnetic waves in the spectral range ultraviolet to infrared (about 350 nm to 2500 nm) can be transmitted. The optical fibers are used in communications technology of a wired message transmission. Normal light sources typically emit light waves at multiple frequencies while laser light is monochromatic and basically has only one frequency. For this reason, laser light can be easily polarized. Lasers can be operated in continuous wave or pulsed. To produce monochromatic laser light, laser diodes or standard lasers corresponding to a higher radiation power are possible.

Semitransparent mirrors reflect a portion of the incident light and transmit another portion of the incident light. Such partially transmissive mirrors (for the range of visible light and for UV light) are available as a commodity and z. B. from the company precision Glas & Optik GmbH, manufactured on long bush 14, D-586740.

Usually vibrate electromagnetic waves z. In different planes, circular or elliptical. With a linear polarization, the waves oscillate only in a single plane.

An embodiment of the invention is illustrated in the drawings and will be described in more detail below. Show it:

1 a schematic representation of a transmitter arrangement for generating with payloads modulated linearly polarized laser light beams with different polarization angles.

2 a schematic representation of a receiver arrangement for recovering the useful signals from the transmitted modulated linearly polarized laser light beams.

3 a schematic representation of linearly polarized light in different polarization planes, wherein the linearly polarized light in each polarization plane is characterized by a different polarization angle phi.

3 shows a schematic representation of linearly polarized light in different polarization planes, wherein the linearly polarized light in each polarization plane is characterized by a different polarization angle phi. In light emitted from ordinary light sources, the light vector has no preferential direction. Vibrations occur in all directions, but always perpendicular to the propagation direction z of the light. If all light vectors oscillate in one light bundle in one direction only, then one speaks of linearly polarized light 3 For example, three cases of different polarization levels are shown schematically: the polarization plane P0, the polarization plane P65 and the polarization plane P90. All polarization planes have the axis z in common, which at the same time indicates the propagation direction of the light.

The position of the polarization planes is defined by the polarization angle phi. For the polarization plane P0 as the reference polarization plane, phi should be equal to 0 degrees. For the polarization plane P65, phi is equal to 65 degrees (phi 65), and for the polarization plane P90, phi is equal to degrees (phi90). The polarization angle phi is between the reference polarization plane and that in the z-axis cutting according to other polarization level measured. The polarization angle phi also identifies the position of the linearly polarized light, in other words: for linearly polarized light with the polarization angle phi equal to 0 degrees, all the light vectors oscillate only in the polarization plane P0. This is schematically in 3 indicated that the imaginary amplitudes of an imaginary half-wave H0 in the polarization plane P0 are (solid representation) .. For linearly polarized light with the polarization angle phi liche 65 degrees (phi65) vibrate all the light vectors only in the polarization plane P65. This is schematically in 3 indicated that the imaginary amplitudes of an imaginary half-wave H65 in the polarization plane P65 are (dashed line). For linearly polarized light with the polarization angle phi equal to 90 degrees (phi65), all light vectors oscillate only in the polarization plane P90. This is schematically shown in FIG 3 indicated that the imaginary amplitudes of an imaginary half-wave H90 in the polarization plane P90 are (dotted representation.).

1 shows a schematic representation of a transmitter arrangement for generating with Nutzsignalen S1, S2, S3, S4 linearly polarized laser light beams B1linmod, B2linmod, B3linmod, B4linmod modulated with different polarization angles 0, 90, 45 and 135 degrees. From the laser beam B1 emanating from the laser L1, a linearly polarized laser beam B1lin with the polarization angle phi = 0 degrees is formed by the polarization filter Pi. For reasons of clarity, the polarization filter P1 is therefore provided with the notation "0" (for the value of the polarization angle). By the modulator MR1 of the linearly polarized laser beam B1lin is modulated as a carrier with the useful signal S1 to be transmitted. Further information on modulation and modulation techniques will follow later. The modulated carrier is labeled B1linmod.

From the laser beam B2 emanating from the laser L2, a linearly polarized laser beam B2lin with the polarization angle phi = 90 degrees (with the notation "90" in P2) is formed by the polarization filter P2. By means of the modulator MR2, the carrier B2lin is modulated with the useful signal information S2 to be transmitted. The modulated carrier is labeled B2linmod. From the laser beam B3 emanating from the laser L3, a linearly polarized laser beam B3lin with the polarization angle phi = 45 degrees is formed by the polarization filter P3. By the modulator MR3 of the carrier B3lin is modulated with the information to be transmitted, the useful signal S3. The modulated carrier is labeled B3linmod. From the laser beam B4 emanating from the laser L4, a linearly polarized laser beam B4lin with the polarization angle phi = 135 degrees is formed by the polarization filter P4. By the modulator MR4 of the carrier B4lin is modulated with the information to be transmitted, the useful signal S4. The modulated carrier is labeled B4linmod.

The modulated carrier B1linmod and the modulated carrier B2linmod are guided onto the partially transmitting mirror M1-2 in such a way that the part of the modulated carrier B1linmod transmitted through the mirror and the part of the modulated carrier B2linmod reflected by the mirror become a common laser beam B1-2 be merged. This contains the transmitted part of the carrier B1linmod with the polarization angle phi = 0 degrees and the reflected part of the carrier B2linmod with the polarization angle phi = 90 degrees.

The modulated carrier B3linmod and the modulated carrier B4linmod are guided onto the partially transmissive mirror M3-4 in such a way that the part of the modulated carrier B4linmod transmitted through the mirror and the carrier B3linmod modulated by the mirror are combined to form a common laser beam B3-4. This contains the transmitted part of the modulated carrier B4linmod with the polarization angle phi = 135 degrees and the reflected part of the modulated carrier B3linmod with the polarization angle phi = 45 degrees.

The laser beams B1-2 and B3-4 are guided on the semitransparent mirror M1-2-3-4 in such a way that the part of the laser light B3-4 transmitted through this mirror and the part of the laser light B1- reflected by the mirror 2 are merged into a common laser beam B1-2-3-4. This laser beam contains a part of the modulated carrier B1linmod with the polarization angle phi = 0 degrees, a part of the modulated carrier B2linmod with the polarization angle phi = 90 degrees, a part of the modulated carrier B3linmod with the polarization angle phi = 45 degrees and a part of the modulated carrier B4linmod with the polarization angle phi = 135 degrees.

The laser beam B1-2-3-4 comprises 4 different modulated "carrier waves" of linearly polarized light, each carrier wave having a different polarization angle. When each modulated carrier wave is considered as an "information channel", the laser beam B1-2-3-4 (with respect to the four existing lasers L1, L2, L3 and L4) comprises a total of 4 payload information channels.

The in the presentation 1 chosen number of 4 lasers is only to be understood as an example. It could also z. B. be much more, z. B. 100 or 1000, depending on the accuracy of the polarization angle setting .. Each of the linearly polarized laser beams can be modulated with another useful signal, so that a total of a very large number of different "useful signal information channels" results.

For the same fundamental frequency of all lasers, the transmission bandwidth for all useful signal information channels is basically no greater than for a single useful signal information channel. This is the case if all the wanted signals require the same maximum bandwidth in the modulation. The transmission bandwidth would increase if lasers with different fundamental frequencies are used.

2 shows a schematic representation of a receiving arrangement for a bundle of modulated linearly polarized laser light beams with different polarization angles.

This receiver arrangement is used to separate the modulated with different polarization angles linearly polarized laser light beams and their demodulation to recover the transmitted useful signals.

The receiver arrangement in 2 is the according to 1 generated laser light beam B 1-2-3-4 (in 2 also designated B) supplied. This laser light beam comprises parts of the 4 modulated carrier waves B1linmod (with the useful signal S1 modulated linearly polarized carrier wave B1 with the polarization angle phi = 0 degrees), B2linmod (with the useful signal S2 modulated linearly polarized carrier wave B2 with the polarization angle phi = 90 degrees), B3linmod ( with the useful signal S3 modulated linearly polarized carrier wave B3 with the polarization angle phi = 45 degrees) and B4linmod. (with the useful signal S4 modulated linearly polarized carrier wave B4 with the polarization angle phi = 135 degrees).

The laser light beam B-1-2-3-4 (B) strikes the semitransparent mirror MA. The part Br of the incident light there is reflected, the other part Bt is transmitted (it penetrates the semitransparent mirror). The reflected part Br strikes the semitransparent mirror MB. The part Brr of the light incident there is reflected; the other part Brt is transmitted. The part Bt of the laser light beam transmitted through the partially transmissive mirror MA strikes the partially transmissive mirror MC. The part Btr of the light incident there is reflected; the other part Btt is transmitted. The partial Brr reflected on the partially transmissive mirror MB is supplied to the polarizing filter P3 '. In the present case, the polarizing filter P3 'transmits only linearly polarized light having the polarization angle 45 degrees (this is the polarization angle of the carrier wave B3). Carrier waves such as B1, B2 and B4 with a different polarization angle can not pass this polarization filter P3 '. The filter P3 'passing part of the modulated carrier wave B3 with the polarization angle phi = 45 degrees is the demodulator D3' supplied, which singles out the transmitted from the carrier wave useful signal S3 and the Rendering device R3 'feeds The portion Brt of the laser light beam transmitted at the partially transmissive mirror MB is fed to the polarization filter P1', which transmits only linearly polarized laser light having the polarization angle phi = 0 degrees (this is the polarization angle of the carrier wave B1). The part of the modulated carrier wave B1 having the polarization angle phi = 0 degrees passing the polarization filter P1 'is supplied to the demodulator D1', which rejects the useful signal S1 transmitted by the carrier wave and feeds it to the reproducing device R1 '.

The part Bt of the light beam B transmitted to the partially transmissive mirror MA strikes the partially transmitting mirror MC. The part Btr of the light beam Bt reflected by the mirror MC is supplied to the polarizing filter P2 '. In the present case, the polarization filter P2 'only linearly polarized light with the polarization angle phi = 90 degrees (this is the polarization angle of the carrier wave B2) .. Carrier waves such as B1, B3 and B4 with a different polarization angle can not pass this polarization filter. The polarization filter P2 'passing part of the carrier wave B2 modulated with the useful signal S2 is supplied to the demodulator D2', which separates the transmitted from the carrier wave useful signal S2 from this and the playback device R2 'feeds.

The part Btt of the laser light beam Btt transmitted at the mirror MC is supplied to the polarization filter P4 ', which transmits only linearly polarized laser light having the polarization angle phi = 135 degrees (this is the polarization angle of the carrier wave B4). The filter P4 'passing part of the modulated with the useful signal S4 carrier wave B4 with the polarization angle phi = 45 degrees is the demodulator D4' supplied, which singles out the transmitted from the carrier wave useful signal S4. and the playback device R4 'feeds.

• a) gleichzeitige Erzeugung von linear polarisierten elektromagnetischen Wellen, wobei jede Welle (B1lin, B2lin, B3lin, B4lin) einen anderen vorgebbaren Polarisationswinkel phi (0 < phi < 180 Grad) hat und wobei jede linear polarisierte Welle von jeweils einer anderen elektromagnetischen Ursprungswelle (B1, B2, B3, B4) abgeleitet wird
• b) auf jede der linear polarisierten Wellen wird eine (durch Modulation zu übertragende) Nutzsignal Information (S1, S2, S3, S4) aufgeprägt,
• c) gleichzeitige senderseitige Einspeisung der modulierten linear polarisierten auf einen gemeinsamen Übertragungsweg,
• d) empfangsseitige polarisationswinkelspezifische Separierung der modulierten linear polarisierten elektromagnatischen Wellen und Trennung der Nutzsignal-Information (S1, S2, S3, S4) von jeder der mit dieser modulierten linear polarisierten elektromagnetischen Welle.

The function and mode of operation of the polarization filters on the send and receive sides are the same. A polarizing filter always selects only one polarization direction from the incident light. This means that on the transmitting side of unpolarized light only the light with a certain polarization direction is selected. On the receiving side, however, the one with a certain polarization angle is selected from a plurality of light beams. The inventive method for transmitting information by means of differently linearly polarized electromagnetic waves as an information carrier on the same transmission path between a transmitter and a receiver arrangement comprises the following steps:

• a) simultaneous generation of linearly polarized electromagnetic waves, each wave (B1lin, B2lin, B3lin, B4lin) having a different predeterminable polarization angle phi (0 <phi <180 degrees) and wherein each linearly polarized wave from each of a different original electromagnetic wave (B1 , B2, B3, B4) is derived
• b) on each of the linearly polarized waves, a (to be transmitted by modulation) useful signal information (S1, S2, S3, S4) impressed,
• c) simultaneous transmitter-side feeding of the modulated linearly polarized to a common transmission path,
• d) reception-side polarization-angle-specific separation of the modulated linearly polarized electromagnetic waves and separation of the useful signal information (S1, S2, S3, S4) from each of the modulated linearly polarized electromagnetic wave.

Even if in 1 Laser are used to generate the electromagnetic waves, the inventive method is not limited to laser (no matter what wavelength range), but generally include any sources for generating electromagnetic waves.

In connection with 1 has already been mentioned that each of the linearly polarized laser beams B1, B2, B3, B4 with a different polarization angle by modulation to be transmitted useful signal (S1, S2, S3, S4) is impressed. By the useful signal (eg speech, music, data) the so-called carrier (the carrier wave with a carrier frequency) is thereby changed (modulated). As a result, the high-frequency transmission of the low-frequency useful signal is made possible. The transmission signal, the modulated carrier occupies a bandwidth dependent on the useful signal in the region of the carrier frequency. The useful signal is recovered at the receiving end by demodulation and separated from the carrier.

By modulation both analog and digital useful signals can be transmitted. Modulation converts the wanted signal into another frequency range. In this case, parameters of the carrier such as amplitude, frequency and / or phase are changed by the useful signal. There are time-continuous and time-discrete (each divided into value-continuous and discrete-value) modulation methods. Representatives of discrete-time modulation methods are the pulse carrier methods. In modulation methods, a distinction is made between linear (as in amplitude modulation) or non-linear (as in frequency modulation) and between analog and digital methods. In addition, there are also special modulations such as pulse modulation and spread spectrum modulation.

All modulated linearly polarized laser beams are simultaneously applied to a common transmission path.

The transmission can z. B. consist of optical fibers or be an optical radio link. The required frequency bandwidth of the transmission path is independent of the number of linear polarized laser beams, provided that all lasers generate radiation of the same fundamental frequency. Common lasers can be well placed in the visible and UV (ultra violet) regions. The frequency bandwidth increases when lasers with different fundamental frequencies are to be used. The various useful signals S1, S2, S3 and S4 to be transmitted are bound to the different polarization angles of the simultaneously transmissible linearly polarized laser beams. The polarization angle phi must be in the range 0 <phi> 180 degrees in order to avoid reception-side superimpositions of useful signals. The fact that each laser beam B1, B2, B3, B4 is generated by a separate laser L1, L2, L3, L4 is equivalent to the fact that each linearly polarized wave B1lin, B2lin, B3lin, B4lin is derived from each other of an original electromagnetic wave. The inventive method can be realized with commercially available components, if a plurality of linearly polarized laser light beams are used as payload information carriers with the same fundamental laser frequency in the range of visible and / or ultraviolet light and optical fiber or an optical radio link as a transmission path.

On the receiving side, a polarization-angle-specific separation of the modulated linearly polarized electromagnetic waves and by demodulation a separation of the useful signals S1, S2, S3 and S4 from the transferred portions of the modulated carrier waves B1linmod, B2linmod, B3linmod and B4linmod.

As shown in 2 The transmitted components of the modulated linearly polarized waves B1linmod, B2linmod, B3linmod and B4linmod are separated from each other according to their polarization angles 0 degrees, 45 degrees, 90 degrees and 135 degrees, and then demodulated to eliminate the desired signals S1, S2, S3 and S4.

The inventive arrangement for transmitting information by means of differently linearly polarized electromagnetic waves as an information carrier on the same transmission path between a transmitter and a receiver arrangement has the following features:
In the transmission arrangement several lasers (L1, L2, L3, L4, ...) are provided. Each laser light beam generated by these lasers can be fed to a polarization filter (P1, P2, P3, P4) for generating a linearly polarized laser light beam (B1lin, B2lin, B3lin, B4lin) with a predeterminable polarization angle phi (0 <phi <180 degrees). , The polarization angles for the individual linearly polarized laser light beams are different. The linearly polarized laser light beams B1lin, B2lin, B3lin, B4lin are each fed to a modulation circuit MR1, MR2, MR3, MR4, which modulates each laser light beam with in each case one useful signal S1, S2, S2, S3, S4). The modulated linearly polarized laser light beams (B1linmod, B2linmod, B3linmod, B4linmod) are fed together on a common transmission path to a receiver arrangement. As transmission path z. B. optical fiber or an optical radio link in consideration. The receiver arrangement comprises polarization filters P1 ', P2', P3 ', P4', which can be acted upon by the modulated linearly polarized laser light beams with the predetermined polarization angles. Each polarization filter is transparent only to a modulated linearly polarized laser light beam having a given predetermined polarization angle. Each polarization filter is connected to a subsequent demodulator D1 ', D2', D3 ', D4'. Each demodulator serves to recover the useful signal S1, S2, S3, S4 from the corresponding linearly polarized laser light beam modulated with this useful signal. This useful signal S1, S2, S3, S4) can each be fed to a reproduction device R1 ', R2', R3 ', R4'. The receiver arrangement is furthermore characterized by the following features:
The linearly polarized laser light beams (B1linmod, B2linmod, B3linmod, B4linmod) which are respectively modulated with a useful signal (S1, S2, S3, S4) are arranged on the transducer side via partially transmissive mirrors (M1-2, M3-4, M1-2-3 -4) merge;
the modulated linearly polarized laser light beams can be fed to the polarization filters (P1 ', P2', P3 ', P4') via receiver-side mirrors via semitransparent mirrors (MA, MB, MC).

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 10216281 [0001]
• DE 10334154 [0001]
• DE 19846573 [0001]

Cited non-patent literature

• "Arrival Time Detection for Polarization Mode Dispersion in Optical Transmission" by Vitaly MIRVODA; University of Paderborn, 2009; Entry of the German National Library Frankfurt am Main, http://d-nb.info/992775345) [0001]

Claims (4)

Method for transmitting useful signal information by means of differently linearly polarized electromagnetic waves as information carrier on the same transmission path between a transmitter and a receiver arrangement, characterized by the following process steps: a) simultaneous generation of linearly polarized electromagnetic waves, each wave (B1lin, B2lin, B3lin, B4lin) having a different prescribable polarization angle phi, where 0 <phi <180 degrees, and wherein each linearly polarized wave is derived from each of a different source electromagnetic wave (B1, B2, B3, B4) b) on each of the linearly polarized waves a to be transmitted by modulation useful signal information (S1, S2, S3, S4) is impressed, c) simultaneous transmitter-side feeding of the modulated linearly polarized electromagnetic waves onto a common transmission path, d) reception-side polarization-angle-specific separation of the modulated linearly polarized electromagnetic waves and separation of the useful signal information (S1, S2, S3, S4) from each of the modulated linearly polarized electromagnetic wave. Method according to Claim 1, characterized by a plurality of linearly polarized laser light beams as useful signal information carriers with the same fundamental laser frequency in the range of visible and / or ultraviolet light and by optical fibers or an optical radio link as transmission path. Arrangement for transmitting information by means of differently linearly polarized electromagnetic waves as information carrier on the same transmission path between a transmitter and a receiver arrangement, characterized in that provided in the transmission arrangement a plurality of lasers (L1, L2, L3, L4, ...) are that each laser light beam (B1, B2, B3, B4) generated by these lasers each with a polarizing filter (P1, P2, P3, P4) for generating a polarized laser light beam (B1lin, B2lin, B3lin, B4lin,) with a polarization angle can be supplied by the polarization filter phi (0 <phi <180 degrees), wherein the polarization angles for the individual linearly polarized laser light beams are different, that each of the individual linearly polarized laser light beams (B1lin, B2lin, B3lin, B4lin) each of a modulation circuit (MR1, MR2, MR3, MR4) can be fed, through which provided with a certain polarization angle p polarized laser light beam (B1lin, B2lin, B3lin, B4lin) with a useful signal (S1, S2, S3, S4) is modulated that the modulated linearly polarized laser light beams (B1linmod, B2linmod, B3linmod, B4linmod) merge and a common transmission path of a receiver Arrangement can be supplied that are provided as a transmission optical fiber or an optical radio link, that the receiver assembly polarization filter (P1 ', P2', P3 ', P4') comprises, which with the modulated linearly polarized laser light beams with the predetermined polarization angles (phi) can be acted upon, each polarization filter is only permeable to a modulated linearly polarized laser light beam, which has a certain predetermined polarization angle, and that each polarization filter with a subsequent demodulation circuit (D1 ', D2', D3 ', D4') is connected by which the useful signal (S1, S2, S3, S4) from the entspr echenden with this useful signal modulated linearly polarized laser light beam can be recovered, and that this useful signal (S1, S2, S3, S4,) each a playback device (R1 ', R2', R3 ', R4') can be fed. Arrangement according to claim 3, characterized in that each with a useful signal (S1, S2, S3, S4) modulated linearly polarized laser light beams (B1linmod, B2linmod, B3linmod, B4linmod) sender-arrangement side via partially transmissive mirror (M1-2, M3-4 , M1-2-3-4), and in that the modulated linearly polarized laser light beams can be fed to the receiver-side via partially transmissive mirrors (MA, MB, MC) to the polarization filters (P1 ', P2', P3 ', P4') are.

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