DE1268191B - Line-sequential color television transmission device, in particular color recording - Google Patents

Description

Line-sequential color television transmission device, in particular color recording. B. R, G, B or corresponding color difference signals to be transmitted and displayed one after the other during playback. Such a sequential system of the three color signals is particularly advantageous in magnetic tape recording, particularly in home recording devices. Here the recording of a complete color television signal according to the NTSC, PAL or SECAM system causes difficulties because the frequency of the color carrier lying in the upper band of the brightness signal is generally outside the recording bandwidth of the recording device. With a line-sequential recording of the color signals R, G, B , these difficulties do not arise because these color signals only need to be recorded in a narrow band. Such a line-sequential transmission of the color signals can also be used in short-circuit systems, in industrial television, monitoring systems, etc.

When playing such a sequential, e.g. B. on a magnetic tape recorded color television signal, however, interference patterns arise in the reproduced Image. If the number of lines is not divisible by 3, the reproduced Picture a particularly disturbing pattern, e.g. B. in the form of horizontal stripes of color that move vertically across the screen.

To avoid this disruption, it is known to adjust the phase position of the one To switch the color cycle assigned to the field from field to field. For example the sequence of colors at the beginning of the field is always switched so that every picture in the first line starts with the same color. To this end the switch that assigns the different colors to the three color signals line by line must be used alternately tapped or distributed, redirected at the beginning of the field. Additional signal sources such as clock generators or the like are required for this.

The invention is based on the object of the reversal described of the switch to simplify the circuitry.

The reversal of the switch is achieved according to the invention by that the switch after a field by one of the vertical sync pulse derived pulse is advanced once more than the number of lines is equivalent to.

The invention is based on the knowledge that with the already in the signal existing vertical sync pulse an additional switching of the switch is possible and that this forwarding causes the fault to be eliminated. An additional signal source for reversing the switch is not required. The pulse used to reverse the switch is always in time correct because it is derived from the signal itself.

The invention is related to the known reversal of the Phase of the color cycle based on the drawings for a signal with 625 lines per image and skip explained. In the drawing, FIG. 1 to 5 shows diagrams for explanatory purposes the well-known line-sequential transmission and reversal of the phase of the color cycle, F i g. 6 switching voltages for the line-frequency switch, F i g. 7 is a block diagram the known record with application of the invention and FIG. 8 is a diagram to explain the reversal of the switch.

According to FIG. 1, the color signals R, G, B are transmitted one after the other, recorded on a magnetic tape recorder and played back.

F i g. 2 shows the colors R, G, B written in the individual lines of the fields for a system with 625 lines per image and line jump. Since the number of lines 625 is not divisible by 3, the result in FIG. Distribution shown in 2. For example, `if an image begins with R, the R, G, B cycle would be completed after 624 lines. With a continuous sequence R, G, B , the last, namely the 625th line of this picture would be written with R and picture 2 (field 3) would begin with color G. F i g. 3 shows that a specific color, here the color R, is offset by one spatial line from field to field, ie lines of a specific color move in a vertical direction. This creates a disruptive pattern in the image, which is noticeable in a highly disruptive manner through horizontal stripes of color that move in a vertical direction.

This interference pattern is reduced in a known manner in that the phase position of the color cycle at the beginning of each field by one or two lines is reversed. In Fig. 4 is the assignment of the color signals to the lines around shifted by a line duration, for example the color R appears in field 2 not. more like in Fig. 2 in line 6 but in line 4 by the line 6 by two spatial lines, i.e. H. a time line is removed. The same applies to the following fields. This reversal of the color cycle results the in Fig. 4 patterns shown.

F i g. 5 shows the pattern of FIG. 4 for the color red. The figure shows that the pattern is now distributed over the screen. A pattern according to F i g. 5 has a less disruptive effect on the screen than a pattern according to FIG. 3, because it's a standing pattern.

In Fig. 7 supplies a video encoder 5, e.g. B. a recording device or a color television receiver, the color signals R, G, B at three output terminals. With a switch 6, the color signals R, G, B are tapped line by line according to FIG. 1, fed to a recording device 7 and recorded there line by line one after the other . The output signal of the recording device 7 is again distributed to the three control electrodes of a color display tube 9 with a switch 8, so that in each case a color signal only reaches the control grid of the display tube 9 assigned to it. The switch 6 is controlled by a ring counter 10, which has three outputs, strobe pulses 1, 2, 3 according to FIG. 6 supplies, controlled. The touch pulses control, for example, three color channels R, G, B permeable one after the other. The ring counter 10 is advanced by line sync pulses from a line 12, for example. In a circuit 13, according to the invention, an additional pulse is now obtained during the vertical blanking time which advances the counter once more than corresponds to the number of lines. As a result, the switch 6 runs ahead by a period of time, so that in a desired manner according to FIG. 8 during the vertical blanking time, the phase of the color cycle is reversed by one line and from the pattern according to FIG. 2 the pattern according to FIG. 4 is created. In the circuit 13, an additional pulse is obtained from the vertical sync pulse, which is counted by the counter 10 in addition to the line sync pulses.

During playback, the switch 8 is again controlled by a counter 11 controlled, which is switched on again by line sync pulses. For example each color signal R is preceded by an identification pulse, which, regardless of the respective Position of the switch 8, when it appears, the counter 11 reverses so that the switch 8 switches the R channel through. This identification pulse can, for. B. only during the vertical blanking time. It can be similar to a color sync signal consist of color carrier-frequency vibrations, the frequency of which is within the recording bandwidth of the recording device, or from a low-frequency alternating voltage (200 to 400 kHz).

Claims (1)

Claim: Television transmission device in which, using a line-frequency switch, three different color signals (R, G, B) representing color components are alternately transmitted line by line and, in order to avoid a disruptive color structure occurring in the displayed image in the case of a signal with a number of lines not divisible by 3 per image Phase position of the color cycle (R, G, B) assigned to a field is switched from field to field by one line, characterized in that the switch (6, 8) increases once after each field by a pulse derived from the vertical sync pulse is advanced than it corresponds to the number of lines. Considered publications: German Patent Nos. 921 950, 950 371, 1023 079, 1025 932; U.S. Patent Nos. 2,301521, 2,739,181, 2,747,013-