DE19635018C2 - Transmission of three-dimensional image information - Google Patents

Description

The invention relates to a method for the transmission of three-dimensional image information, in which a first and egg ne second sequence of pictures with different angles captured images is used. The invention relates also a method for receiving such a transmitted three-dimensional image information and respective circuit arrangements for carrying out the transfer or emp fangs.

A known method for generating and displaying dreidi Dimensional pictures is introductory in DE 32 14 021 A1 wrote. After a polarization process is done for two Image channels each used a television set, each of which a Pola risk is set. Each television set radiates one Sequence of pictures taken from different angles out. By means of polarizing glasses, which each eye one Only the polarized light of one of the image sequences the viewer receives a three-dimensional one Image impression. To transmit the two sequences of images from Sen The two TV sequences must be in separate to the television sets th television channels are transmitted. In correspond accordingly, the recording of the images and their processing processing up to transmission and reception in the televisions take place separately, so that two full transmit or receive channels are required.

DE 39 01 103 C1 describes a method for transmission described reoscopic television pictures, in which each Stereo image pair only one stereo field and the difference both fields are transmitted and the receiving side Image pair from the transferred field and the difference right is constructed. The difference is in the Verti keyed gaps in the transmitted stereo field.  

The difference and the drawing file can also be a data be subjected to reduction.

EP-0 204 006 A1 is stereoscopic for transmission Television pictures provided, a difference picture to temporally come prime and key into the vertical blanking interval. to then color coding takes place.

The object of the invention is the aforementioned Methods and circuit arrangements to specify the dreidi Dimensional transmission of images with less effort and simpler means to perform.  

The method according to the invention advantageously turns for the transmission of three-dimensional image information conventional television technology in combination with nowadays available digital image processing measures. A two between the channels present picture difference, from the emp a second image channel on the output side for generating the three-dimensional effect is derived in the for the main channel of the Verti, which is not used anyway transmitted calabary blank. The 3D process is thus over thermally compatible with regard to receivers that do not have 3D Have reception facilities. In addition, the are to be in principle applying signal processing methods known.

The invention is explained in more detail below on the basis of the exemplary embodiment shown in the drawing. A transmitting device 100 and a receiving device 101 are shown . The transmitter is supplied with two video signals Q1, Q2, which are recorded with two cameras, which record the scene to be transmitted from different angles in a common image plane. In a Subtraktionseinrich device 1 , an image difference is formed, which outputs the image difference of the two channels. The image difference essentially contains image edge information. For further processing, this difference in image is converted analog to digital in a converter 2 . In a device 3 , the image difference is subjected to source coding. Known, standardized methods for coding moving or still images or image sequences are suitable for this purpose, for example such methods according to the standardization bodies JPEG or MPEG. The coding device 3 serves to compress the data stream with respect to the existing redundancy. A data buffer 4 , which we will describe in more detail below, serves to buffer the data over time. Subsequently, the redundancy-compressed, coded data are converted digitally to analog in a converter 5 . In parallel, the main channel is delayed in a time delay device 10 by the processing time of the device 2 . , , 5 to compensate. The main image of the source Q1 is, as is known, a color coding 7 , z. B. subjected to the color standards PAL, NTSC or SECAM. These standards have in common that the image conventionally transmitted there does not occupy all the lines provided. At the beginning and at the end of the picture, during the so-called vertical blanking interval, lines are transmitted which do not contain any picture information that can be assigned to this picture. If necessary, there are a few lines filled with digital teletext information. In the free lines of the vertical blanking interval, the compressed image information which is present at the output of the D / A converter 5 is now keyed in by means of the device 8 . The data applied to the converter 5 on the output side have the format of a conventional video signal. They are therefore color-coded in a conventional way in a device 6 . A timing device 9 is used to control the data buffer 4 as a function of the keying into the vertical blanking interval by means 8 such that the data of a fully coded difference image are available for keying during the vertical blanking interval.

It is also possible to receive the generated signal with conventional TV sets, since the additional information causing the 3D effect is present in the lines of the vertical blanking interval that are not visible to the 2D image. A system according to the invention thus works downwards compatible. The bandwidth occupied by the television signal is not increased. The reduction factor for reducing the video signal Q2, which is achieved by the difference formation and the data compression, is based on the ratio of the visible lines of a field occupied by the 2D image to the number of additional lines occupied by the difference information in the vertical blanking gap. A ratio of 287/4 = 71 results for the PAL color television standard. With source coding algorithms available today that are to be processed by the device 3 , such a reduction factor can be achieved without further ado. As is known, the data rate at the output of the A / D converter 2 is approximately 150 Mbit / s, after the source encoder 3 there are approximately 3 Mbit / s, the buffer memory 4 sets this again to 150 Mbit / s for insertion into the lines of Vertical blanking gaps around.

To determine the image difference between the video signals Q1, Q2, it is alternatively possible to carry out a prediction instead of the difference formation 1 shown in the drawing, in which an image of the signal Q1 is used as a reference image and the images of the 2D channel are formed by a prediction become.

The combined signal emitted by the scanning device 8 is emitted via an antenna 11 and received by the receiver 101 with an antenna 20 . At the receiver end, PAL decoding 21 is first carried out for all lines, that is to say the visible area and the vertical blanking interval. The conventional 2D image is then separated in a device 22 from the data encoded in the vertical blanking interval. The conventional 2D image is fed to a screen 24 and possibly delayed by a timer 23 in order to compensate for the running time through the other channel. In the latter processing channel, the processing steps carried out in the transmitting device 100 are undone again. There is an analog-to-digital conversion in an A / D converter 25 , a source decoding in a decoder 26 and data buffering in a data buffer memory 27 which prepares the time-compressed data received in the vertical blanking interval again in a timely manner so that they form the 3D effect can be displayed simultaneously with the image of the other channel. The data is then digitally converted analogously in a D / A converter 28 . On the output side there is a signal corresponding to the difference signal formed in the transmitter with the device 1 . This difference signal is superimposed on the main image by a summation device 29 and leads to a display device 30 . The light emitted by the screens 24 , 30 is polarized horizontally with a polarizer 31 or vertically with a corresponding polarizer 32 . In order to recognize the 3D effect, a viewer must use glasses which have different polarization filters for the right and left eyes, so that the left and right eyes of the viewer can again take the two images separately.

Claims (5)

1. A method for transmitting three-dimensional image information, in which a first and a second image sequence (Q1, Q2) with images taken at different angles of view are supplied, an image difference is determined between images of the first and second image sequences (Q1, Q2) , the picture difference is coded by means of a digital redundancy-reducing coding ( 3 ), the pictures of one of the first and second picture sequences (Q1) in visible lines of a television picture in accordance with a color television standard which comprises lines of a vertical blanking interval not occupied with picture information for this picture sequence, are transmitted, and the coded data are transmitted in lines of the vertical blanking interval, the coded data being converted digitally to analog and subjected to color coding in accordance with the television color standard, and are then linked to the video signal during the lines of the vertical blanking interval. 2. The method according to claim 1, characterized in that a prediction was carried out to form the image difference that is between the temporally corresponding images of the first and second image sequence is formed. 3. A method for receiving three-dimensional image information transmitted according to a method of claims 1 to 2, in which the lines of the image including the vertical blanking interval are color-coded, the coded data contained in the lines of the vertical blanking interval are separated ( 22 ), which in the visible lines of the television picture are displayed on a first display means ( 24 ), the coded data are redundantly decoded, from the decoded data and the pictures contained in the visible lines of the one of the first and second picture sequences, the pictures of the other the first and second image sequences are restored ( 29 ) and displayed on a second display means ( 30 ). 4. Device for performing the transmission according to one of claims 1 to 2, characterized by means for providing the first and second image sequence (Q1, Q2) with images taken from different angles, means ( 1 ) for determining an image difference between the images the first and second picture sequences (Q1, Q2), to which pictures of the first and second picture sequences can be supplied, means ( 3 ) for digitally reducing the redundancy-reducing coding of the picture difference, means ( 7 ) for generating a television signal with pictures in visible lines and ei ner vertical blanking interval with lines not visible in these images, to which the images of one of the first and second image sequences can be fed, means for digital-to-analog conversion ( 5 ) of the coded data and this means ( 6 ) for color coding and means ( 8 ) for keying the signal output by the color coding means into the lines of the vertical blanking interval. 5. A device for performing the reception of a transmitted according to one of claims 1 to 2 television signal according to claim 3, characterized by means ( 21 ) for color decoding of the received television signal including the contained in the vertical blanking NEN image lines, means ( 22 ) for separating information contained in the lines of the vertical blanking gaps, to which the signal emitted by the means ( 21 ) for color decoding can be fed, means ( 26 ) for redundancy decoding of the separated information to which the information can be fed, means ( 29 ) for restoring the images of the others the first and second image sequences of the decoded information and the images contained in the visible lines of the television signal, and display means ( 30 ) for the restored images and display means ( 24 ) for the images in the visible lines of the television image.