DE2935328C2 - - Google Patents

Description

The invention relates to a still image storage system according to the Preamble of claim 1.

According to US-PS 40 90 223 it is known with such a the resolution of video storage systems improve that with the number of lines of standard television standards work, but their resolving power is not for the Screen display of printed documents is sufficient. This becomes too storing still image, such as a printed document, with doubled the number of lines, for example 1050 lines instead of the normal 525 Lines, but with a picture sequence halved compared to standard television standards frequency, recorded. A magnetic tape device is included for storage Four rotary heads are provided, which freeze the still image in four Record the following skewed tracks on the magnetic tape. The however, four consecutive tracks do not contain Multiple copies of the same still image, but single a quarter of the information in the still image.

According to US-PS 40 13 876 it is known to be a documentation system, the data to be documented on documents, Stores microfilms or microfiches by creating them update new documents. The archive documents recorded with the help of video cameras. The Image information is re-created using a computer compiled or supplemented and then printed out or on a microfilm or the like.

According to US-PS 40 10 365 is a gyro-stabilized op table scanning system known, such as in Ra keten or the like is used for target tracking. To ensure the high level of operational reliability required for such systems enough of an image of four detectors sampled line by line at different times. One with tap provided delay line equalizes the time under separates the signals supplied by the detectors and superimposed corresponding pixels. this leads to an improvement in the noise of the scanned image.

The object of the invention is a still image storage system according to specify the preamble of claim 1 with noise, for example through their inclusion or storage To free most of the still images from the noise equips.

The solution to this problem is specified in claim 1.

Since the noise is statistically distributed, it increases by overlaying the image information one time the still image, however, the noise is not.

To provide still images for the overlay, be preferably provided an education according to claim 2.

To reinforce the still images by overlaying them back again so that the stored superimposed Still images reproduced by commercially available devices or can possibly be saved again, is preferably a Training provided according to claim 3.

To luminance components of chrominance components in one Freeze still image separately from the noise is before trains an education according to claim 4 provided.

To use the system immediately a television playback device To be able to dine is preferably an education according to claim 5 intended.

To be able to archive the overlaid still images, be preferably provided an education according to claim 6.

An archive with relatively quick access results through the training according to claim 7.

To a magnetic tape image storage device as a storage device To be able to use device is preferably an education after Claim 8 provided.  

In order to overlay the data of the storage device To be able to feed still images with an adjusted frequency preferably provided an education according to claim 9. A particularly simple embodiment adapted to the task of the buffer is specified in claim 10.

The invention is based on exemplary embodiments described with reference to the accompanying drawings:

Fig. 1 schematically shows a basic structure of a first embodiment of the plant,

Fig. 2 schematically shows a basic structure of a second embodiment of the plant,

Fig. 3 shows the plant 1 of FIG. With more details and additional devices,

Fig. 4 shows a daughter plant which can work with the system according to Fig. 1 or 2,

Fig. 5 shows schematically a first embodiment of the image superimposing circuit,

Fig. 6 shows schematically a second embodiment of the image superimposing circuit.

In the system shown in FIG. 1, a still picture 10 (for example a slide A ) is taken several times, for example four times, by means of a television camera 11 , but this number is usually higher (for example eight to sixteen times) by means of a magnetic tape image recorder 12 recorded. The image information of the multiply recorded still image 10 is available for output from the device 12 when required and can be overlaid in an image processing device 13 for amplification and noise reduction. The noise that z. B. is due to an imperfect magnetic tape or to the television camera 11 , namely because of its statistical character is pressed by such an overlay in the background. The still image 10 is thus available again at the output of the device 13 with reduced noise. A next still picture 10 (for example a slide B ) can then be recorded and made available in the same way as repeatedly overlaid, so that an archive of noise-reduced still pictures 10 can be created. In the device 12 , a normal magnetic tape with an hour of recording time can be used to store several thousand still images 10 , each of which is repeated several times. Each still image 10 is provided with an index number and is accessible via an index number recognition device. The device 12 is provided in a standard equipment with a connection for a computer control, by means of which cutting processing can take place. It is also part of the standard equipment that the still images 10 can be individually provided with an index number in order.

In the device 13 , a solid-state individual image memory 18 and an overlay circuit 28 ( FIG. 3), which allow an image overlay, are provided. The superimposed image information can be taken directly from the output of the device 13, but are usually stored for over previous archiving on a video disk 20, so that one - for example in live TV - has a direct access to selected still images 10th The storage quality of conventional video storage disks 20 is sufficiently good that no subsequent noise reduction is required. The belt of the device 12 may be used 21 as the master tape for copying by means of a gene ständi archiving serving second magnetic tape Bildaufzeich voltage device.

In a modified system according to FIG. 2, a single image buffer is provided in 15 between the camera 11 and the device 12 , with which a single image can be stored as a still image 10 from an image sequence. This still image 10 is then, as described in connection with FIG. 1 ben, repeatedly recorded by means of the device 12 .

The system according to FIG. 1 is shown in more detail in FIG. 3, additionally with the possibility of transferring the image information from the single image memory 18 in the device 13 via a modulator / demodulator 28 to a data line.

As already stated, each individual still image 10 is recorded on the tape in the device 12 many times by means of the camera 11 . In order to be able to call up the positions in which the still images 10 are recorded on this tape, each individual still image 10 on the tape is identified with an address. Normal electronic editing systems allow such addressing; only electronic control elements need to be provided, which command that addressing at predetermined positions be followed. A time code generated by the device 12 and accompanying video data can also be used to identify each individual still image 10 for later retrieval.

Individual still images 10 are thus recorded by means of the device 12 , and the position on the tape which is assigned to each still image 10 is marked. A standard tape with a recording time of one hour takes about ten thousand individual still images 10 , each repeated eight times. At the beginning of the tape an archive index is recorded, which contains the address of each stand picture of the 10th During operation, this archive index is loaded into the frame store 18 .

The tape in device 12 serves as the main archive register. Access to a specific still image 10 on this tape can typically take one to two minutes in the device 12 ; this is often too long a time.

For this reason, the individual still images 10, which are identical to one another, are first superimposed via a time base corrector 14 and a decoder 16 for the continuous decoding of Y , I and Q signals in the frame memory 18 . The frame memory 18 can be constructed from MOS elements according to British patent application 6 585/76 or US patent application 7 64 148. The capacity of the single image memory 18 is sufficient if it can store a complete television image, possibly in digital form. At each pixel location of the single image memory 18 , the pixels of successive identical still images 10 , which are stored on the tape of the device 12 , are added. If e.g. For example, if there are eight identical still images 10 and each pixel is converted to digital form with an accuracy of eight bits, the capacity at each pixel location in the frame memory 18 must be eleven bits, as explained in more detail below with reference to FIG. 5.

In order to prepare a still image 10 so that it is suitable for broadcasting or checking, the content of the single image memory 18 is divided by the number of still images 10 repeated. The data generated in this way can then be recorded in digital format on a video storage disc 20 . The video storage disc 20 should have a capacity for storing 10 to 100 still images 10 in a computer-compatible form (usually a main code followed by the data and a parity code). From the video storage disk 20 , the still images 10 stored on it can be transferred to a single image memory, from which the still images 10 can be removed as quickly as a program sequence for a program requires, for example 1 to 5 still images 10 per second.

Although the video storage disc 18 can provide video data at normal television speed, reading into the video storage disc 20 must be slower.

The data of a superimposed still image 10 can also be converted back into an analog format for visual display via a digital-to-analog converter 22 , so that they are suitable for direct input into a television system via an encoder 23 .

The system of FIG. 3 receives still images 10 directly by a television camera 11. However, it is, as shown in Fig. 2, also possible to first save the captured still images 10 from the television camera 11 in a single image memory 15 and from there to the magnetic tape recorder 12 . The still images 10 can also be supplied directly from the television camera 11 to the individual image memory 18 .

The system can therefore operate in several operating modes:

• 1. Repeated recording of still images 10 via the video camera 11 by means of the magnetic tape recorder 12 . Reading from the device 12 via the time base corrector 14 and the decoder 16 in the frame memory 18 , in which a superposition of several identical still images 10 follows. The overlaid still images 10 are stored on a video storage disc 20 to enable random and quick access for use during a broadcast.
• 2. Still images 10 stored on the video storage disc 20 are output via the digital-to-analog converter 22 and the encoder 23 in order to be stored again for an archive by means of a further tape recorder 21 .
• 3. Moving images run over the decoder 16 to the frame memory 18 , which performs a stop trick so that individual still images 10 (without overlay) can be stored on the video memory plate 20 . Each individual still image 10 recorded on the video storage disc 20 is then repeatedly stored by means of the tape recorder 12 .

The system is controlled by a computer 15 , for example a standard DEC LSI11 mini-computer, with an associated storage disk. The computer enables a sequential access to desired individual still images 10 , which are retrieved from an archive store, as well as a format of the data corresponding to these still images 10 for the purpose of recording on its storage disk in a sequence which enables access to the still images 10 in the sequence as required for broadcasting purposes. An optical control display unit and a keyboard 25 can be used to input and display image numbers etc. in the computer 15 . Still images 10 are to be superimposed in an image overlay circuit 28 to reduce noise. The combination with and access to the various elements in the system is done by normal techniques such as z. B. are described in US Pat. No. 4,148,070.

It is also possible to transfer the content of either an archive memory or the video storage disk 20 via a standard computer telecommunication connection, e.g. B. the modulator demo dulator 29 to transfer to a second system, which has a similar computer with a disk and a single image memory. In Fig. 4 an example of one of the type plant is shown. The data are received by the system according to FIGS. 1 to 3 via a data line with a frequency that corresponds to the normal telecommunications frequency. In practice, this can be 9600 baud. By means of a computer 41 , which receives the data via a modulator-demodulator 40 , the data are converted into a form which is stored on a video storage disc 42 and subsequently in a transmission by accessing the video storage disc 42 via a frame memory 43 , a digital-analogue Converter 45 and an encoder 46 can be used. A control display unit and a keyboard 44 are assigned to the computer 41 .

Several such plants, as shown in Fig. 4, can use the system of FIG. 1 to FIG. 3 to cooperate with gear to the archive memory.

An image overlay circuit 28 with a single image memory 18 , which has a capacity of 11 bits for processing still images 10 from 8-bit images, is shown schematically in FIG. 5. The 8-bit data comes from decoder 16 in FIG. 3 and runs through an adder 50 into a frame memory 51 .

Is the same still image has been recorded eight times 10, each pixel of the still image 10 of a still image is 10 ge stores are stored until the eight still images 10th The incoming data are added to the corresponding data in the frame memory 51 in the adder 50 . So if the data of a certain incoming pixel indicate a peak level 100 for white, after 8 frames in the frame memory 51 the stored peak level has increased to 800, ie there is an eightfold amplification. For this reason, 11 memory bits are required to store the increased crest level. In order to obtain a gain of one again, the data extracted from the frame memory 51 are multiplied in a multiplier 52 by the factor 1/8.

In an embodiment of the image superimposing circuit 28 image memory with single 18 of FIG. 6 is an 8-bit memory is required in the frame memory 51, since the multiplier 52 between the adder 50 and the frame memory 51 is connected. When the multiplier 52 multiplies the data supplied to it by a factor of 1/2, the frame memory 51 receives only half of the incoming 8-bit video data. For a pixel with a peak level 100 for white, the stored value is at the end of a stored still image 50, at the end of the next still image 75, at the next but one 87.5, etc. until it is close to 100 after 8 still images. If a single image memory 51 with a lower storage capacity is also required for this training, its noise suppression is nevertheless lower.

The diqital adder 50 and the multiplier 52 can be implemented in a known manner, e.g. B. in US Pat. Application 8 41 519 described.

The noise reduction arrangements according to FIGS. 5 and 6 can be provided in duplicate to both the luminance and chrominance components up The video data to verar. This video data must be decrypted before processing.

Is it in an arrangement according to FIG. 5 or FIG. 6 he wishes countries the number of Su to be superimposed still images, to alter, for example, the packing density on a tape or the degree of noise reduction, can dial bare factors for the multiplier 52 in a fixed value memory (ROM) can be saved.

Claims (10)

1. Still image storage system, with an image information of at least one still image ( 10 ) storing in block form storage device ( 12 ), in particular a magnetic tape image recording device, and with one of the stored image information for playback further processing image processing device ( 13 ), characterized in that the Storage device ( 12 ) stores the image information of one and the same still image ( 10 ) several times in block form and that the image processing device ( 13 ) superimposes the multiple stored image information of one and the same still image ( 10 ) for noise reduction. 2. Installation according to claim 1, characterized in that the image processing device ( 13 ) additionally has a single image memory ( 18 ) which stores the image information blocks of the still image ( 10 ) for the overlay. 3. Plant according to claim 2, characterized in that the image information stored in the memory device ( 12 ) mation blocks of the still image ( 10 ) of the image processing device ( 13 ) can be fed in succession and that the image processing device ( 13 ) one of the respectively supplied image information in the frame memory ( 18 ) stored image information adding adder ( 50 ) and a multiplier ( 52 ) which multiplies the stored image information by a predetermined factor. 4. Plant according to claim 2 or 3, characterized in that the frame memory ( 18 ) is a decoder ( 16 ) is switched on, which separates a luminance component from a chromi nance component in the supplied image information from each other and that an encoder ( 23 ) the luminance components te and the chrominance component after processing in the image processing device ( 13 ) combined. 5. Plant according to claim 4, characterized in that the frame memory ( 18 ) emits digital signals and is connected to the encoder ( 23 ) via a digital-to-analog converter ( 22 ). 6. Installation according to one of claims 1 to 5, characterized in that an archive memory ( 20 ; 21 ) is provided for archiving the image information of the still image ( 10 ) which is processed by the image processing device ( 13 ). Is 7. Installation according to claim 6, characterized in that the archive memory (20) out as a video disk (20). 8. Installation according to one of claims 1 to 7, characterized in that the memory device ( 12 ) designed as a magnetic tape image recording device is connected via a time base corrector ( 14 ) to the image processing device ( 13 ). 9. System according to one of claims 1 to 8, characterized in that the image information of a still image ( 10 ) a buffer (in 15 ) can be fed, the image information of this still image ( 10 ) during the multiple writing of the image information one and the same Still image ( 10 ) temporarily stored in the memory device ( 12 ). 10. Plant according to claim 9, characterized in that the intermediate memory ( 15 ) is designed as a solid frame memory ( 15 ).