DE1194446B - Color television system with line-frequency switching - Google Patents

Description

Line rate switching color television system The invention concerns -a color television system with interlaced and with a line frequency Switching in the receiver, - their frequency by line sync pulses and their Switching phase is determined by a control signal that is derived from the vertical synchronous mixture is removed. Such a line-frequency switching is -for example with PAL color television system and required with the SECAM system. The object of the invention consists of the vertical sync mix of a conventional television signal to derive a control signal that is used to determine the correct switching phase of a line-frequency switching in the receiver is suitable.

It is already known from the different from grid to grid Distance between the first line sync pulse and the last posterior satellite in Vertical synchronous mixture to derive a control signal and this for identification of a grid or to achieve the same switching phase of a line-frequency Switch in the first line of each picture. With a television system with an odd number of lines per image, in which the Switch is to switch after each line, this solution has the disadvantage that The control signal obtained after two rasters because of the odd number of lines change the phase position of the line-frequency switch in an undesirable manner by 180 ° would. This would have the consequence that the transmitter and receiver with regard to the switching phase are temporarily out of sync, causing color errors.

It is also known to avoid this error during the vertical retrace time additional pulses - to be transmitted, which correspond to those of the line sync pulses in the Bring the frequency-synchronized changeover switch in the receiver to the correct switching phase. The insertion of such additional impulses, which are mostly modulated onto the color carrier and are therefore taken from the color modulator, is not always possible. This solution is unsuitable, for example, when two encoders are used for the purpose a fade should work in sync or if a receiver also then should already run with the correct switching phase of the line-frequency switch, if no color is transferred yet.

The invention is based on the object, the disadvantages of the known Avoid procedures and with as little change as possible in the conventional Signal determining the correct switching phase of the line-frequency switch to enable. The invention is that the vertical sync mix so is built up that it is just after its beginning at a certain point in time every fourth raster has the same pulse train and the pulse shape in this Time is used to determine the switching phase.

Although there is known a color television broadcasting method in which line-frequency switching between two color signals for a period of four Raster remains unaffected and then for the duration of four further rasters The sequence of the two color signals is switched over in each grid. By the invention solved the problem during the continuous, unaffected line frequencies Switching the correct switching phase of this line-frequency switching in the receiver but is not covered. Also about the structure of the transferred Synchronous pulse mixture is .not stated: In one embodiment of the Invention becomes the first to the last posterior after every fourth grid The following line sync pulse is omitted and the pulse shape at this point in time used after the last satellite to determine the switching phase. In this Point in time, an impulse appears only after every fourth raster. It is also possible, to modify or increase the amplitude of an impulse at a certain point in time modulate. For example, the specific point in time is after the start of the vertical synchronous mixing queried with an interrogation pulse and the presence of a pulse for generation of a pulse used to determine the switching phase.

The solution according to the invention has the advantage that the conventional Vertical synchronous mixing can be used with little modification. In addition, all encoders connected to a primary clock system can then be used as well as all Receiver can be synchronized in the same cycle. Through this a cross-fading between different programs is simplified. This is of particular advantage when fading with a wireless over a distance incoming signal should take place, which is not connected to the local clock generator is.

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

Fig. 1 shows that. Vertical sync mix of a known television signal for five consecutive grids; F i g. 2 shows the synchronous mix of F i G. 1 in simplified form; in Fig. 3 is the application of the invention to one Receiver for the PAL color television system explained on the basis of a block diagram; F i g. 4 shows the principle of a further embodiment of the invention.

In FIG. 1, the vertical synchronous mixture consists of the line synchronizing pulses 1, the upstream 2, the vertical sync pulses 3, the downstream 4 and the Color sync pulses 5. The vertical line 6 is the beginning of the Vertical sync pulses 3 indicated. The half-line frequency switching meander 7, the is to operate the line-frequency switch is in the desired switching phase shown. During the period marked by circle 7, should the switching meander in every fourth grid in the switching phase shown in dashed lines to be brought. In this period 7 the pulse series 1_ to 4 is now queried, whether on. there is an impulse at this point. This can be done with one with the rising edge at time &. or with the falling edge at the end of the vertical sync pulse 3 delayed generated query pulse can be achieved. In grid 3, the first Line sync pulse 8, which causes the switching meander because of the expired in two rasters would bring odd number of lines in the wrong switching phase, according to the invention omitted. Then a pulse appears again in the period 7 in the grid 5, the the meander 7 again gives the correct switching phase. This is based on the fact that after four grids an even number of lines has expired. 'Through the on the vertical sync mix 1, 2, 3, 4 following line sync pulses 1 is then: the frequency of the line frequency Toggle switch controlled during the following lines, while the switching phase is automatic remains: It is also possible to have an impulse with special in every fourth grid to send a large amplitude or to modulate a pulse. During the raster 2 up to 4 the switching phase remains unaffected.

F i g. 2 shows the pulse scheme according to FIG. 1 in a simplified form. An interrogation pulse 10 is generated in the receiver, which is offset by a fixed time 4t at time t1 of the end of the vertical synchronous pulse 3 . This interrogation pulse 10 is used to interrogate the period 7 after the last posterior satellite. In the grid 1, the interrogation pulse 10 finds a line sync pulse 1 within its range and scans it up so that a pulse is produced at the output of an amplitude limiter stage finite to the limit value 11. In grid 2, there is no pulse in the period 7 of the interrogation pulse 10 because of the interlace. There is therefore no signal at the output of the amplitude limiter stage. In the grid 3, the normally occurring first line sync pulse after the posterior satellite is omitted according to the invention. In the grid 4, because of the interlace in the area of the interrogation pulse 10, no line sync pulse appears either. Only in grid 5 are the same conditions as in grid 1. The interrogation pulse 10 and the synchronous mixed series 1, 2, 3, 4 are fed to an And-'lor, which therefore only sends a pulse to determine the correct switching phase after every fourth grid of the line-frequency toggle switch.

F i g. 3 shows a practical embodiment of the connection for a color television receiver for signals of the so-called PAL color television system 16, 1I. The reference carrier j is fed from a terminal 18 to the synchronous demodulator 16 directly and to the synchronous demodulator 17 via a 90 "phase focus element 19 and an 18W phase switch 7.0 . The switch 20 is used to switch the reference carrier for the synchronous demodulator 17 line-frequency by 180 "in accordance with the switchover of a modulation axis on the transmitter side. The switch 20 contains two diodes which are alternately patted by a half-line frequency switching meander generated in a multivibrator 21 containing two transistors The output voltages of the synchronous demodulators 16, 17 are fed via filters 32, 33 to terminals 34, 35 and are available there as video-frequency color signals Q 'and 1'.

The complete video signal V is fed from a terminal 22 to a separation stage 23 which controls a deflection circuit 24. The deflection circuit 24 supplies line-frequency pulses 25 which synchronize the switching meander of the multivibrator 21 via a line 26. The output signal of the separation stage 23 also reaches an integration stage 27, which responds to the vertical synchronizing pulses 3 and thus controls a gate pulse generator 28 which generates a gate pulse 10 according to FIG. 2 generated and fed to a gate circuit 29. The gate circuit 29 is also supplied with the output signal from the separation stage 23. According to FIG. 2, a pulse 30 arises at the output of the gate circuit 29 only in every fourth raster, which is fed via a line 31 to the multivibrator 21 to determine the correct switching phase of the switching meander 7. The line-frequency pulses 25 thus determine the frequency of the switch 21. The circuit would thus already be functional once the multivibrator 21 has been brought to the correct switching phase. The pulse 30 on the line 31 defines the correct switching phase of the switching meander 7 after every fourth grid. The generation of the query pulse 10, which is delayed by a fixed amount compared to the vertical sync pulses, can be done, for example, by triggering an oscillating circuit with the vertical sync pulse 3 which, after a time At, reaches a certain voltage value and thereby generates the query pulse 10 in an amplitude filter.

F i g. 4 shows a further possibility of obtaining a pulse for determining the switching phase from the synchronous mixture. Line-frequency pulses 36 are derived from the flywheel-synchronized line deflection circuit of the receiver and occur without any irregularity at the beginning of each line. The line sync pulses 1 of the received synchronous mixture are brought into a phase position such that they coincide in time with the line-frequency pulses 36. The two pulse trains 36 and 1 are fed to a gate circuit, which only then-. emits a pulse if a pulse is only present in one of the two pulse series 36, 1 at one point. According to the invention, a line sync pulse 1 is now omitted at a point 37 in the synchronous mix. At this point, a pulse 38 arises at the output of the gate circuit, which pulse is used to determine the switching phase of the line-frequency switch. For example, the pulse series 36, 1 can be fed together to a grid of a tube. Usually the impulses cancel each other out there. Only at time 37, ie after every fourth raster, is a line sync pulse 1 missing, so that the tube is then made conductive by the only pulse 36 that is present and emits a pulse 38. This solution has the particular advantage that it can practically not respond to disturbances. This is due to the fact that not the presence of a pulse, but the absence of a pulse is used to obtain the pulse 38 determining the switching phase and interference pulses usually additional pulses pretend, but do not completely eliminate existing impulses.

Claims (7)

Claims: 1. Interlaced color television system in which two Raster give a complete picture with an odd number of lines, and with a line frequency Switching in the receiver, its frequency by line sync pulses and their switching phase is determined by a control signal obtained from the vertical synchronous mix, characterized in that the vertical synchronous mix (1 to 4) is constructed so that at a certain point in time (7) after its beginning it is only after every fourth Grid has the same pulse shape and the pulse shape at this point in time (7) is used to determine the switching phase. 2. Color television system according to claim 1, characterized in that after every fourth grid at the specific point in time a line sync pulse (1) is omitted. 3. Color television system according to claim 2, characterized in that after every fourth raster the first line sync pulse (8) after the last posterior satellite (4) is omitted. 4. Color television system according to claim 2, characterized in that the received synchronous mixture (1 to 4) and a generated in the receiver, flywheel-synchronized, uninterrupted, line-frequency pulse series (36) are fed with the same phase of a gate circuit, which only in the absence of a line sync pulse (1 ) responds in the received synchronous mixture (1 to 4) and emits a pulse (38) which is used to determine the switching phase (FIG. 4). 5. Color television system according to claim 1, characterized in that that at the specific point in time (7) a pulse of the vertical synchronous mixture (1 to 4) is changed in amplitude after every fourth grid. 6. Color television system according to claim 1, characterized in that at the specific point in time (7) a pulse of the vertical synchronous mixture (1 to 4) is modulated after every fourth grid. 7. A color television system according to claim 3, characterized in that is produced from the vertical synchronizing pulse (3) an interrogation pulse (10) which falls in the period (7), in which the last Nachtrabanten (4) nearest the line synchronizing pulse (1), and that the synchronous pulse series (1 to 4) and the interrogation pulse (10) are fed to an AND gate (29) whose output pulse (30), which occurs only in every fourth grid, is used to determine the switching phase of the line-frequency switch (20) (F i g. 2, 3). Documents considered: German Auslegeschrift No. 1106 803.