DE1267246B - Circuit arrangement for synchronizing several video signal generators - Google Patents

Description

Circuit arrangement for synchronizing several video signal generators If there are several video signal generators, e.g. B. several tape recorders or different It is known to transmitters whose output signals are to be used alternately for example with a clock the signals of the video encoder according to line and image to synchronize. This is to ensure that both the lines and the grids of the individual video signals of the encoder coincide in time and at fading or mixing the signals from the various encoders, no interference occurs.

It is a color television system with line frequency switching known (PAL), in which at the beginning of each line color sync signals from color carrier frequencies Vibrations are transmitted with phase switched from line to line. Such Color sync signals can be used in the receiver to generate a reference carrier more constant Phase for the demodulation and also for the synchronization of a line frequency Switch serve.

It is also known to use color synchronous signals with color carrier frequencies Omit vibrations during the vertical blanking period so that they can synchronize vertically do not bother.

It is also proposed that the color burst signals during the vertical blanking time omit over such a period that the last burst before and / or the first color sync signal after the vertical sync pulse from grid to grid has the same phase. This ensures that after the vertical sync pulse the same conditions always exist when the color sync signals are reinstated and disturbances in the synchronization of the switch can be avoided.

In such a system, a full one runs within four grids Pulse cycle from, d. that is, a certain pulse cycle repeats itself only in each fourth grid. This is due to the line jump and the odd number of lines per complete picture and by the requirement that the last or the first color sync signal before or after the vertical sync pulses from grid to Grid has the same phase. To when crossfading or mixing such a signal To avoid interference, it is not only necessary to have a synchronization for Line and picture to be provided. In addition, the different grids must match, d. That is, a certain grid of the four grids of an encoder that form the cycle must coincide in time with the associated grid of another encoder.

From the line sync pulses, the upstream, the vertical sync pulses and no signal can be sent to the posterior to identify one of the four grids derive. The satellites have before and after the vertical sync pulse to last or first line sync pulse different from raster to raster timing. However, this only allows you to choose one of two grids, however not used to identify any of four consecutive rasters will.

The invention is based on the object of the color television system described to enable identification of one of the four grids and thus the additional Synchronize the video signal generator to a specific grid.

The invention is based on a circuit arrangement for synchronization multiple video signal generators in an interlaced color television system, one odd Number of lines per image and a line-frequency switch, with each at the beginning Line transmit color sync signals with the phase switched from line to line and are omitted during the vertical blanking period for such a period are that the last burst before and / or the first burst has the same phase after the vertical sync pulses from grid to grid, where a complete pulse cycle takes place in four rasters.

The invention consists in that in addition to the known line and picture synchronization the individual encoder a color sync signal with one for the vertical sync pulse Temporal position in which a color sync signal is certain only in every fourth grid Phase or timing to the vertical sync pulses occurs for synchronization the Encoder is used on a specific one of the four grids.

For example, the first or second burst after the vertical sync pulse or the last or penultimate color sync signal exploited the vertical sync pulse. The evaluation takes place z. B. in that the signal coming from the encoder is fed to a gate that is triggered by a vertical sync pulse derived key pulse only approximately during the duration of the color sync signal to be evaluated is controlled permeable, and its output voltage to synchronize the Giver serves.

The invention assumes that in the underlying color television system at a certain point in time after or before the vertical sync pulse only in each fourth raster a color sync signal appears, which is therefore used for synchronization the encoder can be used on one of four grids.

The invention is explained in more detail below with reference to the drawings.

FIGS. 1 to 3 show waveforms to explain the invention underlying pulse schemes and the invention, while in F i g. 4 the block diagram an embodiment of the invention is shown.

F i g. 1 shows the color television signal in the temporal vicinity of the vertical sync pulse for an interlaced system and 625 lines per complete picture. The signal contains line sync pulses Z, pre-satellite VT, vertical sync pulses V, post-satellite NT and color sync signals F. The phase position of the color carrier-frequency oscillations contained in the color sync signals F, which varies from line to line, is indicated by the different direction of the arrow. Points in time that are perpendicular to one another from one grid to the next but one grid have a time interval of 625 lines. As a result of the requirement that the color sync signals always begin with the same phase after the vertical sync pulses V, the result in each case for the first color sync signal after the vertical sync pulse is the one shown in FIG. 1, which is conditioned on the one hand by the line jump and on the other hand by the odd number of lines. If, for example, the first color sync signal in the fourth raster has the phase shown by the arrow pointing upwards, then in the second raster (2 raster = 625 lines later) the color sync signal must have the opposite phase because during this time an odd number of lines has expired and the line frequency Switchover runs continuously even during the vertical blanking time.

F i g. 2 shows the associated line-frequency switching and leaves recognize that this switchover occurs in four successive rasters to the vertical sync pulses V has a different phase position. If now z. B. the well-known synchronization the video signal generator to the vertical sync pulses V and the line sync pulses Z and, for example, if grid 1 and grid 3 coincide in time, they are correct both line sync pulses and vertical sync pulses exactly match in time. Nevertheless, the synchronization is not sufficient because, as shown in FIG. 2 shows in In this case, the line-frequency switching in the switching phase does not match and in the event of a cross-fading or mixing, disturbances in the synchronization of the line frequency Switch occur in the receiver.

According to the invention, one of the four grids, which together make one complete pulse cycle, identified by the fact that a point in time before or after the vertical sync pulses V is evaluated, in which only in every fourth Raster a color burst appears. For example, with a touch pulse 9 with a time delay of t. for the first vertical sync pulse V the video signal queried at the time of the first color sync signal 5 of the grid 3. If during a color sync signal 5 appears at this time, this is an indication that that it is grid 3. The query could also be made during the second Raster take place at the time of the first color sync signal 6, because also in this Time a color sync signal appears only in every fourth raster. The times the first color sync signals 7, 8 could only be evaluated in that Synchronous demodulators are provided, which are also based on the different phase position respond because at these times in two successive grids of the a total of four raster color sync signals, but with different phase positions, appear.

F i g. 3 shows the blanking time for the same length from grid to grid the color sync signals F, the blanking time usual in the NTSC system being dashed is indicated.

F i g. 4 shows a block diagram of the invention. A clock generator 10 synchronizes two magnetic tape machines 12, 13 on line and image in a known manner via a line 11. The magnetic tape machines 12, 13 deliver video-frequency color television signals to terminals 14, 15, which are to be mixed with one another or faded over, for example in a studio. The output signals of the magnetic tape machines 12, 13 are fed according to the invention via lines 16, 17 to two gates 18, 19 , which according to FIG. 1 are controlled by a keying pulse 9 derived from the vertical sync pulses V after each vertical sync pulse during the duration of the first color sync signal 5 of the raster 3. The output signals of the gates 18, 19 are fed to two circuits 20, 21. The output signal of the clock generator 10 is fed to a gate 24, which is also controlled to be permeable by the key pulse 9 at time t1 after the vertical synchronizing pulses V. The output voltage of the gate 24 is fed to the two circuits 20, 21. The opening of the gates 18, 19, 24 therefore takes place as a function of the vertical synchronizing pulse V of the signal supplied to the respective gate.

In the circuits 20, 21, the temporal position of the color sync signals coming from the gates 18, 19 to the color sync signals coming from the gate 24 is evaluated. As soon as these color sync signals are shifted from one another in time, a standing value is obtained which controls the speed of the magnetic tape machines 12, 13 via lines 22, 23 in such a way that the color sync signals coming from the gates 18, 19, 24 and thus also associated raster of the video encoder 10, 12, 13 coincide in time, so that the line-frequency switching according to FIG. 2 has the same phase position for all video signal generators. In series with the gates 18, 19, 24, for example, selective means can be provided which respond only to the color subcarrier frequency.

It is also possible with the manipulated variable obtained in stages 20, 21 to switch a modulator or a clock for a video signal so that they belong together The grids of the individual donors coincide in time. Switching or reversing can be done electrically or mechanically.

Claims (6)

Claims: 1. Circuit arrangement for synchronizing several Video signal transmitter in a color television system with interlaced, an odd number of lines per image and a line-frequency changeover, with color sync signals at the beginning of each line are transmitted with phase switched from line to line and during the vertical blanking time are omitted over such a period that the last burst before and / or the first color sync signal after the vertical sync pulses from Grid to grid has the same phase, with one complete in four grids Pulse cycle runs, characterized in that in addition to the known line and Image synchronization of the individual encoders (12, 13) with a color sync signal (5) such a to the vertical sync pulse (V) temporal position in which only in each fourth grid (3) a color sync signal of a certain phase or temporal position to the vertical sync pulses (V) occurs to synchronize the encoder (12,13) is used on a certain of the four grids. 2. Circuit arrangement according to Claim 1, characterized in that the first (5) or second color sync signal (8) is used after the vertical sync pulse (V). 3. Circuit arrangement according to claim 1, characterized in that the last or penultimate color sync signal is used before the vertical sync pulse (V). 4. A circuit arrangement according to claim 1, characterized in that the signal coming from the encoder (12, 13) is fed to a gate (18, 19, 24) which is connected to a tactile pulse (9) derived from the vertical sync pulse (V) only approximately during the Duration of the color sync signal to be evaluated (5) is controlled permeable, and its output voltage is used to synchronize the encoder (12,13). 5. Circuit arrangement according to claim 4, characterized in that a standing quantity is obtained from the temporal position of the output voltages of the gates (18, 19, 24) to each other, which acts on the encoder in such a way, for. B. the speed of serving as encoder magnetic tape machines (12,13) controls so that the output voltages coincide in time. 6. Circuit arrangement according to claim 5, characterized in that that the manipulated variable acts on a modulator or clock generator of a video encoder.