WO2011141529A1 - Holographic live presentation system and method for the live transmission of a holographic presentation - Google Patents

Abstract

The invention relates to a holographic live presentation system, comprising: - a recording studio unit (100), having a camera (110) and a video encoder (106) for generating a digital transmission signal from the signal of the camera (110) and - at least one conference room unit (200), having at least one video decoder (206) for converting the digital transmission signal into a transmission signal suitable for a projection device (210), and further having a holographic projection device (210), which comprises at least one image projector (211) and a transparent reflection medium (212) that is arranged obliquely to the viewing plane of an onlooker in the conference unit (200; 200'; 200''). The recording studio unit (100, 400) is provided with a network controller (105) for transmitting and/or receiving the digital transmission signal via an external remote data transmission line (301, 303). The conference room unit (200) is provided with a network controller (205) for receiving and/or transmitting the digital transmission signal via the external remote data transmission line (301, 303). At least two data channels are present, either together in one line or in a bundle comprising a plurality of lines. Via at least one control line (302, 303), the network controllers (105, 205) are connected to each other and additionally to a network control unit (325). A switching unit that can be actuated by means of the network control unit (325) is provided on each network controller (105, 205) for switching between the data channels.

Description

Holographic live presentation system and method for live broadcast of a holographic presentation

The invention relates to a holographic live presentation system and a method for live transmission of a holographic presentation.

Holographic projections beyond the Pepper's Ghost Prin ^¬ zip have long been known. For this purpose, an image is projected onto a transparent, but reflective surface, which is arranged obliquely inclined to the viewing axis of the observer ^¬ . In front of the eye of the beholder, there is a spatially suspended image projection that seems to be behind the projection plane.

This principle is also used in the teleprompter and the head-up display.

Holographic projections attract the attention of the viewer to a great extent and are therefore suitable especially for marketing actions. Furthermore, life-size projections of people are possible who seem to present themselves on a stage to an audience, but are actually in a distant recording studio. Thus, for example, live presentations can be made by leaders of companies, without having to be physically present, which travel times are reduced to the arrival to the nearest studio. Unlike a normal image ^¬ transmission and projection on monitors or screens, where only because of the projection way to is to ^¬ shiver constantly aware that the switched-per Videoübertra ^¬ supply person is actually not present the illusion of holographic projection is so good that the viewer the projected person classifies at least ge ^¬ danklich as present and can hardly escape in particular the effect of the body language of the person.

In PCT / WO2010 / 007423 it is disclosed to transmit an image picked up at one place ers ^¬ th video signal to produce hologra- fischer projections by commercially available video conferencing systems to a second location. The ^¬ se are usually based on the usual in the Internet packet-wise data transmission over the TCP / IP protocol. Only with a sufficient bandwidth of the line and under optimal conditions can thus be carried out theoretically interference-free transmission. In fact, the transmitting station does not affect the transmission paths of the data packets and thus on the Übertragungsge ^¬ speed. However, the data stream may stall or break completely during transmission, and it comes to dropouts in image and / or sound. This ma ^¬ chen the transmission is not difficult to understand, but rob the viewer the illusion of three-dimensional appearance, which can produce an error-free holografi- specific projection. Even a non-faulty, but slow data transmission destroys the illusion by long latencies. Synchronous lip Übertra ^¬ conditions holographic projections are thus achieved in the known system only in the ideal case, in which attempts by a subsequent, receiver-side Fehlerkorrek ^¬ ter compensate for transmission errors.

Furthermore, it is provided in known teleconferencing systems that image-in-picture proj ections are effected by media, which are kept at the receiving station. If the person whose image is being transmitted wants to present graphics, photos or even videos, then this media in the receiving station must be superimposed by an operator with the holographic projection. The speaker thus has no direct impact on the off ^¬ choice of additional media, the start and stop of the presentation of the media and not to other parameters such as the lighting or the sound in the auditorium. Unlike a presentation on the ground, where the presenter can control the selection and presentation time of prepared charts, he has to rely on interaction with an operator in the known system.

Object of the present invention is therefore to improve a HO lografisches live presentation system of the type mentioned so that by for trouble-free transmission ^¬ the illusion for the viewer of a seemingly three-dimensional picture can be perfected.

This object is achieved by a holographic live presentation system having the features of claim 1.

An associated method for live transmission of a holographic presentation is defined in claim 8.

The system according to the invention is based on the fact that a plurality of high-bandwidth, redundant data transmission paths are provided between a transmitting station and a receiving station, on which the transmitting station simultaneously transmits the encrypted transmission signal. The transmit signal is a video coded or combined audio / video signal encoded according to a conventional CODEC. It may also be provided with other system specific parameters e.g. For remote control additional functions are added.

The data paths are monitored by the network controller, which at least in each transmitting station, so when recording ^¬ studio, and at the receiving station, wherein the conference room unit, once each are present and which are interconnected via a further data connection.

The data connection is made via broadband connections, in particular via fiber optic networks. To transmit a high-definition video stream is a bandwidth of 100 Mbit / s desirable and of at least 20 Mbit / s he ^¬ conducive.

The transmission signal is according to the invention not just sent, but it will ge ^¬ create a feedback loop, so can be re gistriert in a network control unit ^¬ whether and at what delay or quality the digital transmission signal his receiver he ^¬ reaches.

This loop can in various ways be directed ^¬ be:

In a first embodiment, the transmitter-side network controller registers the data packets that are applied to the remote data transmission lines and announces in a test signal these data packets simultaneously to the network control unit, using a control line with a lower bandwidth can be used. Of the data received in the receiving unit, only core information is also sent to the network control unit, so that running ^¬ time and data losses can be determined in the network control unit.

This feedback is advantageous in a remote network control unit, which is spatially neither in ei ^¬ nem recording studio nor in the conference room unit be ^¬ and therefore also needs to be connected to these units via remote data transmission lines.

Are data transmission lines sufficient bandwidth is available, then also the complete transmit signal in parallel to the network control unit ^¬ averages.

The registration, announcement and verification of the data packets preferably takes place in the network controllers with such high frequency that the data packets are individually monitored, not just blocks of data packets.

On the receiver side not only refreshes ^¬ elle transmitter data line is monitored preferable but also any to- additional backup data line. If an error tolerance threshold on the current transmitter data line is exceeded, the network controller takes over the data packets from the backup data line, provided that the error rate on this line is at least not higher than on the transmitter data line.

In the transmission mode can be provided that when registering errors a complete line switching is effected until the error rate on the main data line has dropped again.

Furthermore, it is possible to temporarily take over the missing or faulty data packets from the backup data line and thus to supplement the gaps in the transmission current on the main data line.

The foregoing description has only referred to the transmission direction from the recording studio to the conference room unit according to a simple holographic presentation system with no feedback.

However, the special advantages of the holographic presentation arise precisely when a person in the recording studio is projected into the conference room unit and there takes place an interaction with a person who is actually present. For this case, cameras and microphones are vorgese ^¬ hen in the conference room unit which transmit an image from the stage and / or the audience back into the recording studio. For a lower image resolution and thus a lower bandwidth is sufficient, but in this case, a transmission in the opposite direction, and at the same time still with the conference room unit leading transmission of the high-resolution transmission signal for the holographic projection.

While in conventional teleconferencing systems the person speaking straight into the picture is moved into the picture, this changeover is not desirable in the case of a holographic projection, because in the case of a true signal source switching, the holographically projected person would constantly be faded in and out on the stage. The Illu ^¬ sion that this person is seemingly on the stage in a dialogue with a moderator who would thus zer ^¬ interfere.

Therefore, the presentation system according to the invention designed for a bidirectional broadcast what it then we ^¬ nigstens are each 1 network controller on each side. Communication can be made via 2 lines.

The advantage of the invention is that always the best and fastest line is automatically selected for the program and that no run time delays caused by complicated error correction algorithms. Especially in the dialogue between two persons, who may even speak, very little delay has to be achieved, so that the illusion of a live discussion can arise and the viewer is not easily aware that at least one of the actors he is sees, is not present at all.

Small delays in the transmission paths of less than 500 ms, preferably 100 ms, mean that both the actors and the audience, this does not bemer ^¬ ken and an authentic impression of a live presentation or live discussion arises. The basic concept underlying the invention, it ^¬ enables it not only to transfer image sections in high quality, but especially an entire image of the whole person in the recording studio from the sole to the crown. As a result, the person in the projection appears full life. Only in this way affects the PRESENTATI ^¬ on authentic to the viewer.

Another advantage of the holographic display system of the invention and the associated method is that unlike traditional video projections is a third dimension as a design tool for Ver ^¬ addition. Even if the projected image is actually mirrored on the flat reflection medium, the spatial impression can be intensified by a deliberate influence of the image in an image com- ponent.

For this purpose, the size and brightness can be changed or superimposed with other real objects or people on the stage as well as with other projected images.

It is advantageous to the transmission signal or the video ^¬ share of the same zuzusch ^¬ sen a spatial depth coordinate value and / or a priority value.

These values control the apparent position of the projected person / object in the depth of the stage space, either in comparison to real persons and objects present there, or in relation to further projected image portions from other sources, for example to a second transmission signal from a second one on ^¬ takeover studio. This allows people in the depths of the stage area to move away from each other and, and superimpose - in a meaningful way according to the spatial positioning.

The spatial depth coordinate and priority may be fixed in advance in a particular set. If, for example, you want to present the lead singer of a band in front of his musicians, the largest spatial depth coordinate and the highest priority are set for the individual from the outset. Appearing Background- also in a real Präsenta ^¬ tion in the background reduced singer and musicians are defined within the holographic presentation by definition smaller priority values and space depth coordinates so that they during the assembly of all the parts of the image in the holographic presentation in the usual from the real stage shows Way to appear in the background.

Furthermore, the spatial depth ^{coordinate value} can be used to simulate camera movements. As a result, little space and equipment expenditure is required in the recording studios, since no real camera movements take place in the depths of the room. Rather, by a continuous variation of the spatial depth coordinate over a certain period of time, the illusion can be caused that the camera is approaching the person or away from it.

It is also possible to recreate the stage of Konfe ^¬ Conference room unit in the recording studio and watch there reference points before ^¬. If the person moves away from the reference points parallel to the Z axis, the depth of the room, then the amount of the value increases or decreases depending on the definition of the zero point. Depending on whether the Person goes forward or backward, the signs of the value change.

The live presentation system according to the invention and the method according to the invention for the live transmission of a holographic presentation are explained in more detail below on the basis of exemplary embodiments and with reference to the drawing. The figures show in detail:

1 shows a live presentation system as a block diagram according to a first embodiment;

FIG. 2 is a block diagram of a live presentation system according to a second embodiment; FIG.

3 shows a live presentation system as a block diagram according to a third embodiment;

4a, 4b a live presentation system as a block diagram according to a fourth embodiment with a first broadcast in various stages; and

5a-5c show a live presentation system as a block diagram according to a fourth embodiment with a second transmission in various stages.

1 shows a holographic live presentation system in a first, simple embodiment, which comprises a recording studio unit 100 and a conference room unit 200.

In the recording studio unit is a camera 110 angeord ^¬ net, which receives an image of a person 101. The taken video signal is a video encoder 106 leads ^¬ leads. In the video encoder 106, a compressed video signal is generated with the aid of conventional CODECS, which is supplied to a network controller 105.

An additional audio module with microphone 115 may paral ^¬ lel receive a tone for the image recording and the audio ^¬ signal also perform the video encoder 106, is able to encode an additional audio track or a combined video / - audio signal to code.

From the network controller 105 of the recording studio unit 100, the encoded video signal is passed as a digital transmission signal via a data channel of a Datenfernübertragungslei ^¬ device 301 to a network controller 205 in the conference room unit 200.

The received transmission signal is decrypted again in a video decoder 206. It is returned in a Videosig ^¬ nal or a combined video / - converted audio signal or into separate channels for video and audio, and then supplied to a projection unit 211 and a speaker 215th

In parallel with the transmission mode, which runs between the network controllers 105, 205 via the remote data transmission ^¬ circuit 301, a control signal via a control line 311 to an ex ^¬ ternal control unit 325 is given by the network controller 105th The latter is again connected to ^¬ via a control line 312 to the network controller 205 in the conference room unit 200th

The data transmission is based on a packet-based data transmission according to the widespread TCP / IP Protocol. As a control signal, for example, an on ^¬ notice of the next data packets is transmitted, while the actual data packet on the remote data ^¬ tragungsleitung is sent three hundred and first

From the network controller 205 of the conference room unit 200, the indexes of the received packets are in turn transmitted to the external control unit 325. In the control unit 325 may thus be understood whether the data packet, the sending of the network controller 105 has previously announced, has been on the opposite side, the network ^¬ factory controller 205 of the conference room unit 200 are received, ^¬ gen.

If, within a defined time threshold, the receiver-side confirmation has not returned to the control unit 325, the control unit 325 causes the network controller 105 on the transmission side to switch the transmitting data channel to a replacement data channel.

This may be an additional data channel within the same remote data transmission line 301. However, it may also be provided to select two completely separate transmission paths as a remote data transmission lines 301 ^¬ each having at least one data channel.

With the command for switching the transmitting data channel and the instruction to the network controller 105, the non-received data packet is sent again and to repeat the transmission sequence starting with this data packet. In this manner it is achieved with a high probability that a nearly flawless Since ^¬ tenübertragung done with very little switchover delays that are imperceptible to the projection in the conference room unit.

Only when both available data channels or remote data transmission lines 301, 303 are disturbed, image dropouts in the conference room unit 200 be ^¬ noticeable. By providing further redundant remote data transmission lines, the security against image disturbances can be further increased.

The switching of the transmitting data channel can, as described above, take place at the moment in which a disturbance has been detected on the previously transmitting channel. However, it can also be provided both data channels or all existing redundant lines simultaneously with the broadcast signal or a test signal to beaufschla ^¬ gen and the receiver side to provide several connected to the network controller receiving units corresponding to test the transmission quality of the redundant lines constantly and possibly a Switching already trigger when it turns out in the ongoing monitoring of the lines that in one of the Ersatzlei ^¬ lines the latencies are shorter, even if the currently transmitting data channel with its latencies is still in the tolerance field. After the switchover of the transmitting data channel, the monitoring is continued on the freed ^¬ become data channel by sending a test signal. Figure 2 shows another holographic live presentation system in which both the recording studio unit 100 ^λ and the conference room unit 200 ^{λ are provided} with further modules, whereas the basic functionality with the data channel monitoring and data channel switching described above works in the same way.

Essentially, an additional encryption of the transmission signal is implemented compared with the system shown in FIG.

In the recording studio unit 100 ^λ , the video encoder 106 is followed by an encryption unit 102. In this, the video signal compressed with a CODEC is again encrypted with a private code, so that it is not possible without the knowledge of the code and the encryption algorithm to decrypt the transmitted signal and to extract the contained image information therefrom.

The thus encoded digital transmission signal is sent via the network controller 105 and the Datenfernübertra ^¬ supply line 301 to the network controller 205 in the conference room unit 200 ^λ , as already described in connexion ^¬ hang with the first embodiment of FIG.

In the conference unit 200 ^λ , the network controller 205 is followed by a decryption device 202, which decrypts the encrypted transmission signal on the basis of the private code and transfers it back into a conventional CODEC format. The still compressed video ^¬ signal can then in the known manner on the video Decoder 206 are converted back into a video signal, which is then further processed within the conference room unit and / or can be fed directly to the projection device 211.

In addition to the supplement with an encryption unit 102 and decryption unit 202, the possibility in the shown in figure 2 embodiment of a holographic live presentation system is provided to allow the 'filmed in the recording studio 100 persons 101 a rear Kopp ^¬ development of what is happening in the conference room unit 200 ^λ , For this purpose, near the reflection 212 is another camera 216 installed device, wel ^¬ che reflects the stage area. Real on stage applicatio ^¬ send people or objects located there be imaged by the camera 216 and shown in the Aufnahmestu ^¬ dioeinheit 100 ^λ on a control monitor 111 in sight of the person one hundred and first Another camera 217 depicts the auditorium. The person 101 can thus not only see the stage with the actions taking place there on the control monitor 111, but also see the reaction of the viewers.

The retransmission of the video signals from the conference room unit to the control monitor 111 in the recording studio unit 100 can be made in the reverse direction via the same transmission paths.

It can also be provided to use the retransmission signal as a test signal and to occupy the spare spare data channel with it. Any transmission errors herein will only be perceived by the recorded person 101. In addition, it is sufficient for the display of the control image on the control nitor 111 when cameras 216, 217 used with low resolution, which occupy a correspondingly low band ^¬ wide.

Finally, it may also be possible to provide an independent video line with low bandwidth for the feedback, for which then additional network controllers must be provided both on the transmitter side and on the receiver side. However, this need not necessarily be monitored in the external Steue ^¬ insurance unit 325.

A further supplement in the embodiment according to FIG ur 2 is made by a remote control system 207. In this way an operator in the external control unit 325 or in the receiving unit 100 is added 'in the location, image, sound, and light presentation fernge ^¬ controls to influence. The additional control instructions can be sent in the data stream of the transmission signal, so that this no separate control lines are required.

Furthermore, the remote control system 207 can be used such that illumination units 114 on the side of the recording studio interact with illumination units 214 in the conference room. For example, the illumination may be synchronized so that the illumination in the recording studio is with darkening of the light in the audience simultaneously turned 100 ', so that as the image 201 appear on ^¬ taken person 101 on the Reflektionsein- direction 212th A still further developed holographic live presentation system is shown in FIG.

Compared with the embodiment described above with reference to FIG. 2, this is further supplemented by the following components:

 Connection of an external teleconferencing system 340 to a conference room unit 200 ";

 Arrangement of a presentation server 240 in the

 Conference room unit 200 "and

 Arrangement of an associated presentation PC 140 in a recording studio unit 100 ".

In order to "be able to demonstrate even more multimedia content on the stage of the conference hall unit 200 next to the image 201 of the transferred person 101 is, on the part of conference space unit 200, a presentation server 240 at ^¬ ordered. This is a presentation data line 331 with a presentation PC 140, which is in the recording studio unit 100.

On the part of the recording studio, the presentation PC 140 is connected to the remote control system 107 and above with a video switch 108. About the video switch 108, referring to the presentation PC multi ^¬ media presentation can be shown on the monitor 111th

Be the intermediary remote control system 107 control commands, such as selecting a presenta ^¬ tion on the presentation PC 140 and the Steuerungsbewe ^¬ movements while navigating within the presentation of the presentation data line 331 to the Präsentati- onsserver 240 "übertra ^¬ gen in the conference studio unit 200th

A prepared presentation is thus loaded on both computers 140, 240 prior to the beginning of the transfer. In this case, even large amounts of data can be moved, because a real-time transmission is not necessary and even small bandwidths for the presentation data lines 331 are sufficient if the timing is ^advanced .

For larger lead times even the transmission of data carriers by post is possible in advance.

Even with presentations in high graphic resolution so very few control commands between the units have 100 during the later broadcast "200" are übertra ^¬ gen. Particularly in the case of three-dimensional volume models from a CAD application, the transmission of a high-resolution video signal would require the same outlay again as is required to transmit the live image of the person 101. But by now a simultaneous operation of similar presentation content is allowed on both sides, it is not necessary to provide additional Datenleitun ^¬ gen high bandwidth for additional multimedia content.

In the conference room unit, the output video signal of the presentation server 240 is sent to an image composer 230. Is in these also the video signal up ^¬ on, which is obtained aufgangsseit ^¬ Lich from the video decoder 206th

In addition, in the illustrated exemplary embodiment of the live presentation system according to FIG. 3, a video signal is still present an external teleconferencing system 340 switched. These are solutions with small studios with a few conference centers in each of which a number of interlocutors is taken on camera while looking at monitors, which maps the other Ge ^¬ interlocutors in a remote studio. By dispensing with the special effect of the holographic presentation, a simple video image of an external teleconferencing system 340 could thus also be presented on the stage 220 and vice versa.

Fig. 4a shows yet another holographic live presentation system. This in turn comprises a conference room unit 200, which is connected to two recording studio units 100, 400. All units are shown greatly simplified compared to Figures 1 to 3 here.

There are in each case between each recording studio 100, 400 and the conference room unit 200 direct connections, between the network controller 105 or 405 with the network controller 205 of the conference room unit 200th

Furthermore, all the units 100, 200, 400 connected to an ex ternal ^¬ control unit 325, which is extended here as Re ^¬ giezentrale 320th

Directed the center to ^¬ acceptance image is shown from the recording studio 100 on a monitor 321st This can be transmitted in lower resolution, as it is only for control purposes. Accordingly, it is possible to transmit directly via the control line 311 with only a small bandwidth. For example, the image of the stage camera 216 (see Fig. 3) is transmitted to a monitor 322 in the control center 300 via the control line 312. The recording picture of the second recording studio 400 appears on a monitor 323.

While the above-described monitoring of the quality ^¬ ty of the transmission signal and the switching between the As ^¬ tenkanälen by the control unit 325 in the background running in parallel, a applicatio ^¬ transmitter in the direction Center 320 cinematographer via the additionally present in the units 100, 200, 400 Remote control devices intervene. He can control image, light and sound and also cause a picture mix.

In Fig. 4a is shown by way of example, as on bueh ^¬ ne 212 in the conference room unit 200, the images of two people 101, 401, together arge.

In order to obtain or even emphasize the holographic effects in the interplay of a plurality of image components, it is provided that a digital spatial depth coordinate value and / or a priority value is also transmitted together with the digital transmission signals. The values can have been encoded into the transmission signal and are then read out correspondingly on the receiver side.

It is true that these transmit signals with a higher Pri ^¬ oritätswert in the mix in the video composer each other image content with a smaller priority value superimposed.

A program with two recording studios 100, 400 shows in a very schematic way the Fig. 4a. In the recording studios 100, 400 persons 101, 401 to be filmed, the Vi ^¬ deosignale of the cameras 110 is processed 410 through the not shown here in detail ^¬ intermediate units and transmitted via remote data transmission lines 301, 302 to the conference studio.

In this case, the person from the first recording studio 100 was assigned a normal priority value. The person 401 in the second recording studio is also filmed and the signal is also transmitted to the conference studio. However, the image signal is a priority "null" respectively associated with a non-visible image portion. As shown by the dashed lines in Fig. 5a indicated, the transmission signal is indeed continuously and can be fed scarf ^¬ tet any time when the image director decides to do so. By this Image signal but assigned an equivalent or higher priority value, the person remains 401 invisible from the second recording studio 400.

Fig. 4b shows the same system arrangement as Fig. 4a. Meanwhile, however, the received second-person video signal 401 has also received a corresponding priority to be displayed on the stage 212. It seems that both persons 101, 401 appear side by side on a stage, but are actually in remote recording studios 100, 400.

Figs. 5a and 5b show a similar structure. In this case, a single person 101 is ge ^¬ filmed in the recording studio 100 and the video signal is transmitted to the conference room unit 200 ^¬ .

At the same time, control images are transmitted to an image control center 320. While the images of the person 101 and the group of persons 401 place in the second receiving ^¬ studio in full body size is Alloc ^¬ voltage of a corresponding space depth coordinate value of the Illusion of a different positioning generated in the depth of the room.

The individual 101 ^λ has been assigned a space depth coordinate value ZI corresponding to a normal body size of about Yl = 1.85 m. The filmed in the second Aufnahmestu ^¬ dio 400 group of people scored assigned a smaller space depth coordinate value Z2, so that they are reduced proportionally with a height Y2 on the reflection medium 212 displayed on the stage.

At the same time, the individual 101 has received a higher priority value on the left. If it moves in the picture from left to right, it enters the group 403 of the persons apparently standing in the background, as shown in FIG. 5b.

In contrast, FIG. 5c shows a section of a program in which the image 201 of the individual 101 as well as the image 203 of the woman from the group of persons have the same spatial depth coordinate ^values , so that they are both projected in natural size and seemingly on the same Height standing on the stage. However, the image 203 of the group of people 401 has a higher priority value and is therefore placed over the image 201 in the image composer. Thus, the group 203 is apparently the front and covers the seemingly behind it A ^¬ zelperson two hundred and first

The addition of the space depth coordinates value and the Priori ^¬ tätswerts are therefore important criteria for the composition ^¬ management of different image sources in the Composer

Claims

Claims:

1. Holographic live presentation system, at least comprising:

 at least one recording studio unit (100, 400; 100 ', 100 "), which comprises at least:

 a camera (110, 410),

 a video encoder (106) for generating a digital transmission signal from the signal of the camera (110, 410) and at least one conference room unit (200, 200 ';

200 "), which has at least:

is a video decoder (206) for converting the digital transmit signal suitable in a for projection ^¬ device (210) video signal, a holographic projection apparatus (210) comprising at least one image projector (211) and oblique to the viewing plane of a to ^¬ schauers in the conference unit (200; 200 ';

200 ") disposed, transparent reflection Medi comprises ^¬ at (212), characterized in that in the recording studio unit (100, 400; 100 ', 100") a network controller (105) for transmitting and / or receiving the digital broadcast signal from an external remote data transmission line (301, 303) and that in the conference room unit (200; 200 '; 200 ") a network controller (205) for receiving and / or transmitting the digital transmission signals arranged over the external remote data transmission line (301, 303); in that the remote data transmission line (301, 303) comprises at least two data channels

 or

that the network controller (105, 205) via at least two data transmission lines (301, 303) are each connected to at least one data channel with ^¬ each other; that the network controllers (105, 205) via at least one control line (302, 303) together and to a network control unit (325) connected ver ^¬; and that in each network controller (105, 205) via the network control unit (325) actuatable ^¬ switching unit for switching between the data channels is provided.

2. Holographic live presentation system according to claim 1, characterized in that in the recording studio unit (100, 400, 100 ', 100 ") at least one microphone

(115) and at least one audio encoder are arranged and that in the conference room unit (200; 200 '; 200 ") at least one audio decoder and a loudspeaker

(215) are arranged.

3. Holographic live presentation system according to claim 1 or 2, characterized in that in the Konfe ^¬ Conference room unit (200; 200 '; 200 ") directed to the Refle ^¬ xionsmedium (212) camera (216) and / or egg ne directed to the viewer camera (217) is angeord ^¬ net and that in the recording studio unit (100, 400; 100 ', 100 ") at least one control monitor (111) is arranged.

A holographic live presentation system according to any one of claims 1 to 3, characterized in that in the conference room unit (100, 400; 100 ', 100 ") between the projection device (211) and the video decoder (206) an image composer (230) for Mixture and / or superposition of image signals from different sources is arranged.

A holographic live presentation system according to claim 4, characterized in that in the recording studio ^¬ unit (100, 400, 100 ', 100 ") a presentation PC (140) is arranged and in the conference room unit (100, 400; 100', 100 ") a presentation server (240) connected to the image composer (230) is arranged.

A holographic live presentation system according to any one of claims 1 to 5, characterized in that an external teleconferencing system (340) via the image composer (230) to the conference room unit (200; 200 ';

200 ") is connected.

A holographic live presentation system according to any one of claims 1 to 6, characterized in that in the recording studio unit (100) the network controller (105) an encryption unit (102) is connected upstream and that in the conference room unit (200; 200 ', 200 ") a decryption unit (202) the network controller ^¬ (205) is connected downstream.

8. A method for live broadcast of a holographic presentation with at least the following method steps ^¬:

a) picking up an image of a person (101, 401) and / or an object in at least (a recording studio ^¬ 100, 400; 100 ', 100 ") by means of at least (a camera 110, 410),

b) generating a digital transmission signal from the Sig nal ^¬ the camera (110, 410) by means of a video encoder (106)

c) transmitting the digital transmission signal by a first network controller (105, 405) on an ex ternal ^¬ remote data transmission line (301, 303),

^■ wherein the remote data transmission line (301, 303) comprises at least two data channels or

^■ wherein at least two remote data transmission ^¬ lines (301, 303) each having at least one data channel is provided, d) transmitting a test signal from the network controller (105, 405) of the recording studio unit (100, 400; 100 ', 100 ") via the data channel to a network controller (205) of a conference unit (200; 200 '; 200 "),

 and or

 Generating and returning a data quality signal from the conference unit (200, 200 ', 200 ") to a network control unit (325),

e) switching the transmitting data channel by means of the network control unit (325) in dependence on the data quality signal and / or the latency between the transmission of the transmitted signal or the test signal and the receipt of the Datenqualitätssig ^¬ nals by the network control unit (325); f) receiving the broadcast signal (in a conference room unit 200; 200 '; 200 ") (by the remote data ^¬ tragungseinrichtung 205) of the conference room unit (200; 200';200"),

g) decoding the transmission signal for conversion into a video and / or audio signal suitable for a projection device (210),

and

h) projecting the video signal by means of a Bildpro jektors (211) a holographic projection apparatus (210) (on a transparent Reflexionsme ^¬ dium 212) which is oblique to the viewing plane of a spectator in the conference unit (200;

 200 '; 200 ") is arranged.

A method according to claim 8, characterized - in that a plurality of recording studio (100, 400; 100 ', 100' respectively connected to the conference studio unit (200; 200 '; 200 ") and the network control unit (325) ver ^¬ connected are

 a space depth coordinate value and / or a priority value from each recording studio (100, 400, 100 ', 100 ") with the transmission signal is transmitted to an image composer (230) in the conference room unit (200, 200', 200")

that mixed in the image composer (230) the received video transmission signals in such a way and / or be Überla ^¬ Gert, that in the video signal for the projection ^¬ device (210) the image information of that transmission signal superimposed on the other transmission signals, which the greatest ordinate value Raumtiefenko- and / or the highest priority value comprises

 and or

 the image information of the transmission signals is increased or decreased in accordance with the assigned spatial depth coordinate.

10. The method according to claim 9, characterized in that the spatial low-coordinate values and / or the Prio ^¬ ritätswerte each shot (100, 400; 100 ', 100 ") are at least set during a time interval.

11. The method according to claim 9, characterized in that the spatial low-coordinate values and / or the Prio ^¬ ritätswerte are variable and of each recording studio (100, 400; 100 ', 100 ") are transmitted with the transmission signal.

12. The method according to any one of claims 9 to 11, characterized in that the spatial depth coordinate values and / or the priority values in the Netzwerksteue ^¬ tion unit (325) are changeable.

13. The method according to any one of claims 9 to 11, characterized in that in the recording studio unit (100, 400, 100 ', 100 ") at least one microphone (115) and at least one audio encoder are arranged and that in the conference room unit (200 ; 200 '; 200 ") we ^¬ nigstens an audio decoder and a speaker (215) are arranged and that with the transmission signal or in the transmission signal, an audio signal via the remote data transmission ^¬ line (301, 303) is sent.

14. The method according to any one of claims 9 to 13, characterized in that in the conference room unit (200, 200 ', 200 ") directed to the reflection medium (212) ge ^¬ directed camera (216) and / or on the viewer ge ^¬ directed camera (217) is arranged and in the up ^¬ acquisition studio unit (100, 400; 100 ', 100 ") at least one control monitor (111) is arranged and that pa ^¬ rallel to the transmission signal, a control signal from the conference room unit (200; 200'; 200 ") in the Recordin ^¬ mestudio (100, 400; 100 ', 100" is returned).

15. The method according to any one of claims 9 to 13, characterized in that in the conference room unit (100, 400, 100 ', 100 ") between the projection device (210) and the video decoder (202) an image composer (230) for mixing and / or superposition of image signals from different sources.

16. The method according to claim 15, characterized in that in the recording studio unit (100, 400, 100 ', 100 ") a presentation PC (140) and in the conference room unit ^¬ (100, 400, 100', 100") a Presentation ^¬ server (240), which is connected to the Bildcomposer (230) are arranged, and that is remotely controlled by means of presen ^¬ tion PC multimedia presentation, which at the same time on the presentation PC and on the presentation server (240) runs.

17. The method according to any one of claims 9 to 16, characterized in that an external teleconferencing system (340) is connected via the image composer (230) to the conference room unit (200; 200 '; 200 ").

Method according to one of claims 9 to 16, characterized in that in the recording studio unit (100, 400; 100 ', 100 ") an encryption unit (102) is connected upstream of the network controller (105) and that in the conference room unit (200; 200'; 200, a decryption unit (202) is connected downstream of the network ^controller (205).