DE3338412A1 - Circuit arrangement for setting the phase angle of vertical synchronising pulses - Google Patents

Abstract

Visual display units are used for optical displays in the case of video games, computers, processors and the like, to which units the vertical synchronising pulses, inter alia, are also supplied from the said units, as well as the actual video signal. Said synchronising pulses often have a non-standard position, so that the image of the visual display unit is displaced in the vertical direction. In addition, a portion of the video signal may even be masked out by the blanking pulse derived from the vertical synchronising pulse. In the case of the invention, the phase angle of the vertical synchronising pulse can be set by means of a delay circuit having a variable delay time, such that the time at which the synchronising pulse occurs is standard again. The non-standard synchronising pulse triggers a first monoflop which drives a second monoflop whose output pulse is differentiated. In this case, the differentiated trailing edge of the output pulse of the second monoflop supplies the vertical synchronising pulse which is located in the correct phase.

Description

Circuit arrangement for setting the

Phase position of vertical sync pulses The invention relates to a Circuit arrangement for adjusting the phase position of vertical Syncllronimpulse in a video display device with a vertical deflection circuit.

The video display devices mentioned are widely used as optical Display required in the so-called video games, both in arcades as well as privately in the apartment. The use as a data display device should also be mentioned, about -in connection with a home or personal computer, which is an increasing Enjoy popularity.

In all applications, the video display device is provided by an external Source - e.g. B. a video game unit or a computer or calculator-usually Video signals supplied via a cable in order to be displayed on the screen of the Video display device to generate. As is well known, the video signal comprises the usual RGB signal as well as the horizontal and vertical sync pulses for the corresponding Deflection circuit of the video display device.

In simple terms, the external source can be viewed as a television station be, whereby the Videosicbtgerät would be regarded as a television receiver. A crucial one The difference, however, is that the one that is of interest here vertical Synchronization pulse at the television station is very precise due to the existing norms and is generated precisely in phase. So there will be a lot of effort on the part of the transmitter the post operated to meet the standard.

In contrast, the external sources mentioned are different Priorities set. In the foreground is z. B., dai with a computer or with a video game with all the data required for display on the video display device can actually be displayed. Such information or Important data that is located at the very top of the screen. At a video game for example, it could contain the number of points a player has in a game while the cursor is located there on a computer. It is therefore primarily a matter of transmitting all data with the video signal, and on the other hand the phase position of the vertical sync pulse takes a back seat, so that it happens that the vertical sync pulse does not conform to the standard.

In practice, one can often observe that the z. B. video signals generated in a video game unit, the vertical sync pulse does not have a standard-compliant phase position. Because the vertical sync pulse controls the vertical oscillator synchronized with the deflection circuit of the video display device, lead to the non-standard vertical sync pulses to a faulty deflection. For the viewer it results then disadvantageously an image advanced in the vertical direction to the Video display device. Another disadvantage is that under Circumstances by the blanking pulse derived from the vertical sync pulse part of the video signal can be faded out. On the screen of the The full information content of the video signal is then not visible to the video display device.

Although the disadvantages described can be avoided in that an exact and phase-accurate vertical sync pulse is generated in the external source is, however, it can be established in practice that the manufacturers of the external Sources - as already mentioned above - initially attach importance to the video signal to transfer as much data as possible. The generation of the vertical sync pulses In contrast, it takes a back seat and only plays a subordinate role. There are also external sources - unlike those described by Swiss Post TV channels - no binding norms, so that the user with the the disadvantages described above is faced.

This is where the invention, on which the object is based, intervenes simple means a correction of the phase position of the vertical sync pulse in the sense of enabling a correct Image can be played back without going into the external source - video game or computers, etc. - to intervene.

To solve this problem is mentioned in the preamble of claim 1 Circuit arrangement characterized by a delay circuit which the vertical Synchronous pulses are supplied and which the vertical oscillator of the vertical Deflection circuit feeds, the delay time of the delay circuit being variable is.

A non-standard synchronous pulse can be caused by the delay circuit to delay or delay its occurrence in a simple manner

Shift in his phase so that he is the desired after the delay has the correct phase position and the vertical oscillator is correctly synchronized can.

In the invention, it is assumed that the external signal source often does not provide vertical sync pulses with phase accuracy. It becomes aware of it apart from interfering with the signal source itself. Instead describes the Invention the way, possibly non-standardized sync pulses within the video display device to correct with simple means and! to shift their phase in such a way that that a perfect picture results.

The delay circuit can be used simply and inexpensively with monoflops implemented, which are available as integrated circuits. Special It is advantageous to use two mono-flops connected in series, where then the falling edge of the pulse of the first monoflop the second monoflop controls and activates.

While the pulse duration of the first monoflop is fixed and is given> the pulse duration of the second monoflop can be changed, see above that overall the delay time is variable.

It is also conceivable that only a monoflop with a variable delay time is conceivable use, however, offers the embodiment of the invention with two in series Monoflops have the advantage of a finer and more precise setting of the respectively desired Delay Time. In addition, most of the commercially available integrated circuits have already two monoflops.

In an expedient embodiment of the invention, the output pulse is the second monoflop differentiated, and a downstream diode causes only the differentiated pulse with positive polarity to the vertical deflection circuit or to the vertical oscillator. So this impulse does not replace that Standard-compliant vertical sync pulse at the input of the delay circuit.

Other advantageous developments of the invention are set out in the subclaims specified and shown in the drawing.

The invention is illustrated below with reference to what is shown in the drawing Embodiment explained in more detail. 1 shows the block diagram of a Video display device to which a video game is connected, Fig. 2-9 several pulse diagrams to explain the circuit according to the invention and FIG. 10 shows a delay circuit with two monoflops.

In Fig. 1, a video game 10 is connected to a video display device 12, in order to display a display required for the video game on the screen of the picture tube 16 to create.

The video game 10 can be viewed as an external source, which in ! known way the RGB signal and - via line 15 - horizontal and vertical sync pulses generated and the video display device 12 feeds. The RGB signal arrives at a signal processing circuit 14 which controls the picture tube 16.

The horizontal and vertical sync pulses become a pulse separator 18 supplied, which the horizontal and the vertical sync pulses from each other separates. The horizontal sync pulses arrive at a horizontal deflection circuit 20, the corresponding deflection coils (not shown) of the picture tube in a known manner 16 dines.

The vertical synchronizing pulses of interest here are initially a delay circuit 24, to which a vertical deflection circuit 22nd which is connected to the corresponding deflection coils of the picture tube 16.

The border of the delay circuit, which is emphasized in the drawing 24 inserted between the pulse separation circuit 18 and the vertical deflection circuit 22 is, it should be shown that the circuit described so far except for the Delay circuit 24 is known per se.

With reference to FIGS. 2 - 9, the mode of operation of the system shown in FIG. 10 illustrated delay circuit explained. Fig. 2 shows a schematically shown Video signal 26, the video signal 26 here being understood to be the RGB signal is.

For a better understanding of the mode of operation, Fig. 3 shows standards-compliant vertical sync pulses 28, of which the dark tactile pulses shown in FIG 30 are derived. Since the phase position of the vertical sync pulses 28 here as is correctly assumed, the dark sampling pulses 30 fall in the image gaps D so that there is a correct picture on the screen of the picture tube 16 and one Correction is not required here.

But if the vertical sync pulse 28 as shown in FIG. 5 does not conform to the standard and thus also the dark sensing pulses 30 in FIG. 6 are shifted in time compared to FIG. 4, on the one hand the picture on the picture tube 16 shifted in the vertical direction, and besides is by dirfalschen Dark tactile impulses 30 faded out a part of the video signal 26, as indicated by the hatched area is indicated in FIG.

The correction required in this case is made by the delay circuit made according to FIG. It comprises two monoflops 40 and 42, which are part of the of an IC (e.g. MC 14538 B from Motorola).

The vertical sync pulse 28 according to FIG. 5 triggers via a gate circuit 44 the monoflop 40, which generates an output pulse 32 according to FIG. 7. The pulse duration 33 of the output pulse 32 is 10 ms, i.e. half the time interval between two consecutive vertical sync pulses 28.

The monoflop 40 is externally connected to the pins provided for this purpose Capacitor 48 and a resistor 50 and a further capacitor 52 wired, that the mentioned pulse duration 33 is established. The resistor 50 is with a positive operating voltage of 12 V applied.

The falling edge 34 of the output pulse 32 triggers via a further gate circuit 46 the second monoflop 42, which according to FIG. 8 is a complementary one Output pulse 36 with a - variable - pulse duration 38 is generated. The latter will determined by the capacitor 54, the fixed resistor 56 and the one change of the resistance value enabling trimmer 58, which is connected to a positive operating voltage connected.

The variable pulse duration 38 is in the embodiment between 2.5 ms and 17.25 ms adjustable.

A resistor 62 is connected to the output 60 of the second monoflop 42 and a capacitor 64 is connected. At the capacitor 64 a close Grounded resistor 66 and a series-connected diode 68, which leads to an output terminal 70.

The last mentioned RC circuit forms a differentiator, which differentiates the complementary output pulse 36. The front sloping leads Edge of the output pulse to a negative differentiated pulse while the trailing rising edge results in a positive pulse, which is shown in FIG the reference number 29 is shown. The diode 68 differentiates the negative Pulse suppressed so that only the positive pulse 29 occurs at output 70. This Pulse 29 is, so to speak, the regenerated vertical sync pulse which is sent to the Place of the non-standard vertical sync pulse 28 according to FIG. 5 occurs.

By setting the trimmer 58 accordingly, the pulse duration 38 - d. H. so the delay time - can be set so that the regenerated Synchronous pulse 29 has a phase-accurate position.

The correct setting of the trimmer 58 and thus the correct choice the delay time required for correction can be made very easily, by changing the resistance of the trimmer 58, the screen of the picture tube 16 is observed. The one from the vertical sync pulse 28 or Dark tactile pulse 30 derived from the regenerated sync pulse 29 can be namely a visual inspection too. In addition, the correct setting can affect the vertical movement of the image on the picture tube 16 can be observed.

The synchronous pulse that is phase-accurate and compliant with the standards after the setting has been made 29 passes from the output terminal 70 to the vertical deflection circuit 22 (see. Fig. 1), whose vertical oscillator is thus synchronized in the right way.

In addition, it should be mentioned that the invention should be used could think of it, simply the vertical position of the picture on the picture tube 16 to be reset or moved (by superimposing the deflection current with a direct current component) if the vertical sync pulse 28 does not conform to the standard occurs. However, this does not allow the video signal 28 to be faded out fix at the top or bottom of the picture. It also results in the solution With the shifting of the vertical picture there is only a relatively small stable setting range, and, in addition, there is an adverse effect on the vertical linearity.

After all, this solution requires a not inconsiderable additional one Energy requirements.

On the other hand, the invention makes possible with simple means an adjustable delay of the vertical sync pulse 28 its phase-accurate Position and thus a perfect picture on the picture tube 16.

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Claims (5)

Claims 1. Circuit arrangement for adjusting the phase position vertical sync pulses in a video display device with a vertical deflection circuit characterized by a delay circuit (24) which the vertical sync pulses (28) and which are the vertical oscillator of the vertical deflection circuit (22) feeds D, the delay time (38) of the delay circuit (24) being variable is. Circuit arrangement according to Claim 1, characterized in that the Delay circuit (24) comprises at least one monoflop (40, 42) 3 circuit arrangement according to claim 2, characterized in that the delay circuit (24) off two monoflops (40, 42) connected in series, and that the pulse duration given delay time (38) of the second, connected to the vertical oscillator Monoflops (42) is changeable. 4. Circuit arrangement according to claim 3, characterized in that a differentiating element (64, 66) is arranged at the output (60) of the second monoflop (42) is, which is followed by a diode (68) to suppress pulses of negative polarity. 5. Circuit arrangement according to one of the preceding claims 3 to 4, characterized in that the two monoflops (40, 42) are integrated into one Circuit are summarized.