DE2011674A1 - Color television system - Google Patents

Description

Color television system The invention relates to a color television system a camera, in whose beam path a rotating disk with sector-like arranged Color filters for the colors is arranged, each with a color filter during is scanning an image in the beam path.

Such systems working according to the so-called sequence process were used in early color television technology. Their disadvantages are there in that when reproducing the individual color components one after the other on the Screen and therefore, if the frame rate is not increased a disturbing flicker of e.g. 16 Hz occurs. On the other hand, she has with such Method used camera versus the usual, one beam splitter and three Cameras containing pick-up tubes have the advantage that only one pick-up tube is required is that the complicated and heavy beam splitter is not applicable and that there are no problems of coverage appear. In the case of cameras with three recording tubes, there must be corresponding positions the color separations of an image can be scanned at the same time.

The present invention is based on the task of a television system to create the type described above, which the generation of a flicker-free Image started without having to increase the number of image changes.

According to the invention, this object is achieved in that cyclically in each case a storage tube that has a multiple.

Query of the stored bag, s- taken, during the Scanning of an image is connected to the camera and the outputs of other storage tubes, in which the previously recorded color signals resulting in a complete color image are stored, each connected to a color channel leading to the playback device are.

Such a color television system produces a seamless color image of e.g. 50 Hz frame rate because in each field time three complete red, Green and blue signals are generated and fed to the viewing device. Only that The alternating frequency of the image content, which is decisive for movement processes, is from 50 to 16 2/3 Hz lowered. However, this is easily permissible, since it prevents flickering entry. It also causes jerky movement of the reproduced image reduced that the change of the picture content in the three colors by one each Field period of e.g. 20 msec takes place out of phase. The new system connects hence the advantages of color cameras working according to the sequential method with the Advantages of color television sets that process the usual three color signals simultaneously exhibit. The three color signals can be processed in the usual way, so that the compatibility is maintained.

The storage tubes used that allow the stored Querying the content several times cannot save the information at the same time and reproduced1 but saving and reproducing must be performed one after the other take place. The transition is made by switching electrical potentials at the Tube causes. The memory must be cleared before a new color signal can be stored be what a time. of just a few microseconds.

Based on the drawing, in which the exemplary embodiments are shown, hereinafter the invention and others Advantages and supplements described and explained in more detail.

Figure 1 shows the basic circuit diagram of a system in which the number of the storage tubes is equal to twice the number of primary colors.

FIG. 2 illustrates the functional sequence of the system according to FIG 1.

In Figure 3, a system is shown, the four with three primary colors Contains storage tubes.

In Figure 4, the function of the system according to Figure is in a scheme 5 clarifies.

In Figure 1, 1 denotes a pick-up tube, for example of the Vidicon type can be. Rotates in the beam path of the objective 2, driven by a synchronous motor 4, a filter disc 3 with sector-like arranged color filters for the primary colors, e.g. red, - green, blue.

The deflection of the electron beam of the vidicon and the speed and the phase position of the synchronous motor are coordinated so that during of scanning an image is only a filter for a basic color in the beam path. With the frame retrace pulses during which the video signal of the vidicon is blanked the pilter of a different basic color is rotated in front of the receiving tube. In lines a, b and c of FIG. 2 illustrate this in more detail. In line a the time is plotted in milliseconds. The scanning of an image takes like Usually 20 insec, corresponding to a frame rate of 50 Hz. In the line is indicated by the letters R, G and B, which Parbfilter I use in the respective Time segment is located in the beam path of the optics of the color television camera. -In the first This is the time period of the Rottilter. Correspondingly, -appears at the exit of the Vidicons the VideoBigaal corresponding to the red component Yidicons is switched via switches S1, 52 ... 56, one of which is closed is, distributed to the memories Spi, Sp2 ... Sp6. The storage tanks Spi and Sp4 take this Color signal of the red color component the memory Sp2 and Sp5 the color signal of the Green component and the memories Sp3 and Sp6 the color signals of the blue component. This is illustrated in line c, which shows which memory is entered is switched to "Registered" in the relevant time segment. It can be seen that the memories are connected to camera 1 cyclically one after the other.

In the first sampling period of the diagram shown in FIG the video signal 9 for the color component red is written into the memory 1. Thereupon the memory Sp2 is connected to the camera in the second time period. Since the Storage tubes are designed so that a simultaneous erasure and writing is not possible, the memory Si, L must be erased during the first time segment will. Accordingly, the memory 8p3 deleted so that this is in the third time period for recording the video signal ready. Accordingly, the contents of the memories Sp4, Sp5, Sp6 and Spi become cyclical turned off. The times of deletion are shown in diagram d. While only one of the switches S1 ... S6 is closed, are of the switches S7 ... S12, which the memory Spi ... Sp6 with the leading to a display unit 5 Connect color channels red, green and blue, three adjacent closed each. This is illustrated in more detail in line e. During the second, third and fourth The switch S7 is closed, so that during this time color signal written into memory Spl during the first time interval reaches the Parb Canal Red and from there to the viewing device. The switch 58 connects-while the time segments 9, 4 and 5 the memory Sp2, in which the during the second Time offset recorded color signal Green is saved over the color channel Grän with the viewing device. Accordingly, the switch S9 closes during of the time segments 4, 5 and 6 the display device to the memory Sp3. During the Periods 5, 6 and 7 will again be the red color component, this time in the memory 5p4 - is included, output. it can be seen that each color component during three Periods of time is reproduced by the display device. Furthermore, at every point in time a complete Barb picture, consisting of the color components red, green and blue reproduced. This means that the image content is only complete after every three time segments changes, which if the frame rate of the pickup tube is 50 Hz, a The alternating frequency of the image content is 16 2/3 Hz. It has been shown that this is not disturbing because the frame rate of the viewing device is 50 Hz and thus a flicker-free image is obtained. A jerky sequence of movements is reduced by the fact that the picture content does not appear after three time segments is changed once, but in three steps.

Electronic switches are used for switches S1 ... S12. This and the memories Sp1 ... Sp6 must be synchronous and in the correct phase with the sampling frequency the pickup tube 1 and the motor 4 are operated. A central control device is used for this provided, which is not shown for the sake of clarity.

In the system according to Figure 1, six storage tubes are provided, each of which is assigned only one specific color. In Figure 3 is the basic circuit diagram shown a television system that contains only four storage tubes. the Camera 1 in turn delivers the color signals red, green and blue sequentially via cyclic Switched switches S15, S16, 847 and S18 on storage tubes 8p7, Sp8, Sp9 and Sp10. In line f of the functional diagram according to Figure 4 are again the Periods of time plotted during which the color signals for the individual color components of the image. The duration of the individual sections is 20 msec, accordingly a frame rate of 50 Uz.

As shown in line g, the color signal is in the first time segment obtained for the red color component and via the switch S15 into the memory Sp7 enrolled. In the following time segments, the color signal is successively for the green component in memory Sp8, that for the blue component in Store Sp9 and the next color signal for the red component in the store SpiO registered. Then switch S15 is closed again, via which this Times the color signal for the green component reaches the memory Sp7.

In contrast to the arrangement according to FIG. 1, the memory is accordingly the classification according to Figure 3 is no longer assigned to a specific color, rather, the color signals of different colors are cyclically stored in one and the same memory Color components cached.

The times for deleting the stored contents of the storage tubes are so short, e.g. 10 / usec, that the deletion is carried out within the frame rewind time can be. Accordingly, the content of the memory becomes Sp8 during the image rewind is deleted, which is followed by writing into the memory Sp8. The delete signals are drawn in line h. In comparison to the arrangement according to FIG. 1, FIG Arrangement according to Figure 3, the distributor tobaltuag for the intermediate storage given signal. somewhat more complex on German color channels. In the execution example this distribution circuit is designed as a twelve-part matrix with switches 520 ... 531, which are switched in such a way that there is always the memory for the three Parb channels that are not currently occupied for German storage. Accordingly are during the first of the time segments entered in FIG the switches S21, S26 and S31 closed and the outputs of the memories Sp8, Sp9 and Sp10 connected to the display device 5. During the second section, while it was going on the color signal of the green color component is written into the memory Sp8, becomes the color signal for the red component previously taken over into the memory Sp7 The red color channel leading to the display unit 5 is supplied via the switch S20. the Switches S26 and S31 remain closed. Before the third period, the The content of the memory Sp9 is deleted, the switch S26 is opened and the switch 817 zad S25 closed, so that now the color signal for the blue component in the Memory Sp9 is written and the color signal contained in the memory Sp8 for- the green component reaches the display device. This opening and closing of the The switch or the bin and readout of the color signals is repeated cyclically the scheme shown in line i of FIG. The three are always last recorded color signals to the display device 5 switched through. The deflection of the electron beam the camera, the speed of the motor driving the filter disc, the actuation the 'switch S15 ... S31 and the operation of the storage tubes Sp7 ... Sp10 must just as in the arrangement according to Figure 1 are synchronized with one another. the the control unit used for this purpose, which is not shown for the sake of clarity is constructed like the known sequence controls.

4 claims 4 figures

Claims (4)

Color television system with a camera, in the beam "path a rotating disk with filters arranged in sectors for the primary colors is arranged, with one BarbSilter during the scanning of an image is in the beam path, characterized in that cyclically in each case one storage tube (Sp1 Sp6), which allows multiple interrogation of the stored image while the scanning of an image is connected to the camera (1) and the outputs further storage tubes (Sp1 ... Sp6), in which the previously recorded, a complete Color signals resulting in color images are stored, each with one to the playback device (5) leading color channel (R, G, B) are connected. 2. Color television system according to claim 1, characterized in that daS with three primary colors, two storage tubes for each primary color (Spl, Sp4; Sp2, Sp5; Sp3, Sp6) are provided, of which cyclically during the recording of a color component of an image, three storage tubes for different primary colors on the three color channels (R, G, B) are connected, a memory tube is supplied with a clear signal and another storage tube is connected to the camera (1). 3. Parbfernsehanlage according to claim 1, characterized in that with three primary colors four storage tubes (Sp7 ... Sp10) are provided, of which cyclically while recording a color component of an image three, the color signals of the storage tubes storing the three color components on the output of the stored Color signals to the three color channels (R, a, B) and one for reading in each generated Color signal are connected to the camera (1). 4. Color television system according to claim 3, characterized in that a switch matrix (S20 ... S31) is provided, the columns of which are connected to the outputs of the storage tubes (Sp7 ... Sp10) and their lines connected to the color channels (R, G, B) are. L e r s e i t e