DE2844112C2 - Video circuit with burn-in protection - Google Patents

Description

In various video circuits, especially in television games, but also in teletext and Viewdata systems it often happens that a certain image remains static on the screen for a long time, so that lighter parts of the image to an accelerated,> local screen burn-in. In particular, it often happens that users forget a Turn off TV game after use, so that, for example, a line pattern of a playing field sometimes stays in front of the screen for a whole night

From DE-AS 23 33 391 a circuit arrangement is already known to prevent burn-in if the distraction is noticeable. Here is a monostable Toggle circuit provided that the Horizontalablenkim- ι> pulse are supplied and which is dimensioned so that the time between setting and automatic resetting is greater than the time between two control pulses. The output of the flip-flop controls the cathode of the picture display tube so that if the deflection voltages fail, i.e. if the flip-flop is automatically reset, the Elek '.- onensirahl is suppressed or defocused.

In the earlier application P 27 23 818 a comparable circuit is described that the picture display tube to protect against the burn-in of the electron beam if the deflection fails. to For this purpose, the blanking pulse of a blanking circuit with those of the electron beam during a period of a «1 electron beam cycle that is not used for representation is blanked, with a constant voltage so that the blanking circuit is effective if the blanking pulses fail is switched so that the picture display tube is darkened.

Such circuits are incapable of prolonged burn-in due to a static image To prevent duration because they respond to the failure of the deflection currents and deflection voltages and the aforementioned burn-in also takes place if -to the distraction doesn't fail.

It is an object of the present invention to provide a video circuit in which burn-in is prevented due to a static image of a long duration.

This object is achieved by the measures specified in the main claim.

It is achieved in a surprisingly simple and inexpensive manner that when the display device neither receives new information nor is it switched off after the expiry of the Timing determined.) Running time the image luminance for all pixels of the screen to zero or to such a low mean value is reduced that burn-in is completely or almost completely avoided will.

For the circuit breaker and the detection circuit and the timing circuit, several embodiments are possible, as in claims 2 to including 13 is described, which is also used in many *> o Combinations can be applied. These embodiments are based on the figures and the figure description explained in more detail. It shows

Figure 1 is a simplified block diagram of a video circuit with a circuit breaker to suppress a luminance signal,

F i g. 2 a timing diagram of the main electrical Signals of the protection circuit,

F i g. 3 is a simplified block diagram of a video circuit with a circuit breaker for disconnection a supply voltage,

4 is a block diagram for suppressing the Luminance signals for a black and white display,

FIG. 5 shows a timing diagram for a video circuit according to FIG. 4,

F i g. 6 shows a detailed partial circuit of a further embodiment with suppression of the luminance signal for a black and white display,

F i g. Figure 7 is a schematic example of the use of a touch contact in a video circuit according to FIG. 4 or F i g. 6,

8 shows a further embodiment of a video circuit according to the invention,

9 shows a wiring diagram for a detection circuit with integration elements,

Figures 10 to 13 show four embodiments of video circuits with a protective circuit for use in color display devices,

FIG. 14 shows a view of the embodiment according to FIG. 13 corresponding timing diagram,

15 is a circuit diagram of a simple detection circuit,

16 shows a simplified block diagram of a with a timing circuit formed by a digital counter circuit.

In Fig. 1 is an operating arrangement 1 with a Image signal source 2 coupled The operating arrangement 1 mostly contains one or more known per se Operating elements such as pushbuttons, touch keys, switches or rotary potentiometers, the latter sometimes operated by a so-called "joy stick". The image signal source 2 is used to build the complete picture information for the selected destination. The image information controls at least one with the Image signal source 2 coupled luminance circuit 3 for supplying a luminance signal to the Playback arrangement 4.

For color reproduction, three luminance circuits 3 are generally used for the so-called R, C and B luminance signals.

The coupling between the operating arrangement 1 and the image signal source 2 can, if desired, via a remote control channel with signal transmission, for example by means of IR radiation.

At least one signal from the image signal source 2 is sent to the detection circuit 5 with a detection output 6 supplied for an electrical detection signal. This detection signal is pulse-shaped and occurs after a Change in the signal taken from the image signal source 2 indicates which signal is one of the image signal source 2 supplied operating signal or a resultant therefrom by processing in the image signal source 2 new signal can be taken. Of course, it is possible for the detection circuit to have two or more to feed multiple signals and to generate a detection signal as soon as at least one of them has a Has change. Examples of this are given in FIG. 4 etc. The output 6 of the detection circuit 5 is coupled to an input 7 of a timing circuit 8 with a time signal output 9. The timer 8 is a known component, such as a monovibrator circuit or a digital counter circuit. The timing circuit 8 is by a detection signal at the input 7 in an initial position, the "O" position brought. So long no new detection

signal is given, the timing circuit works in that, for example, a capacitor voltage accumulates monotonously in time and after a certain time determined by the components lets the monovibrator overturn or in that, controlled by a clock signal, the counter setting up to a selected one maximum count increases. At the end of the selected time, the timer emits an OTC output signal at output 9. However, if a new detection signal appears before the selected time in has expired. the timer is brought back to the "O" position. The time constant of the timer is chosen to be much longer than the time that occurs between information changes during normal use of the system, for example in the order of a minute or longer. As soon as the situation arises that there is no change in the image information for a time longer than the selected time

SVif'rit * \ y ^rr l '"' ac ^ icrnal OTT" ¹ ρΓ7ί * ΐισι u / pretrn

The output 9 of the timer 8 is marked with a> o In this example, input 10 of a protective circuit 11 is coupled directly to the luminance circuit 3. The protective circuit 11 is set up in such a way that that this completely or partially suppresses the luminance signal as soon as the timer has reached the maximum:; Position and remains in this position until a restart is given. That way will avoided that a screen in the display device 4 is burned in by the fact that a still picture from a computer system, a teletext system, a j < > TV game or the like. When not in use, for example, bright boundary lines are still on one reproduces a fixed part of the screen with high intensity. Precisely because other parts of the screen are not burn-in, even rather small differences in intensity η can later have a visually disturbing effect.

The course of events is shown in the timing diagram of FIG. 2 shown. Line 20 therein shows the pulses of the detection signal and line 21 shows a characteristic variable of the timing circuit, for example increasing linearly from "0" to a maximum value "ma \". If / u 'at time r, "a detection signal occurs, the timer is switched to the" 0 "position and this takes place again at time t _m - ■ etc. without the" ma.v "position being reached. Only if nothing has happened for a long time. this time switch reaches the position "max" at the point in time i " and remains in this position until, for example, at the point in time f .. a new detection signal appears. The line 22 shows the output signal OTC 'of the timer circuit, here arbitrarily "" 0 as "ON" or "I" in the normal state and "OFF" - going in the "max" position. The output signal OTC brings the protection circuit into the “OFF” position, as shown by curve 23, which ultimately suppresses the luminance signal Y for black-and-white reproduction, denoted by curve 24, between t and t, completely or for the most part.

F i g. 3 shows a further embodiment. In this and in the following figures the same reference symbols are always used for corresponding elements

Elements 1, 2, 3, 4, 5 and 8 have the same function as in FIG. 1.

The figure now also includes a supply arrangement IZ, for example a battery, which supplies the remaining parts of the video circuit with a supply voltage via a normally conductive transistor 13, the base of which forms the input 10 of the protective circuit. As long as the OTC signal at the output 9 of the timing circuit 8 is "ON", the transistor 13 is conductive and the video circuit is provided with a supply voltage. If, for example, the OTC signal is "OFF" at the point in time /, the transistor 13 blocks the supply voltage, so that, of course, OTC will now remain "OFF". The timing circuit 8 now does not need to have a hold function. Although it is sufficient to block only the supply voltage of the timing circuit 8, it may be desirable to block the entire voltage. This is useful when using battery power to extend the life of the battery. A further advantage occurs when a television receiving arrangement is used as the display arrangement 4 when the luminance signal, modulated onto a carrier, is fed to an antenna input 14 of the receiver. When the supply voltage is removed, the carrier also ceases to exist, which means that most receivers start to noise and in this way give the user an audible warning. Another possibility is to put this switch in the standby position for receivers with a so-called "standby" switch as soon as the supply voltage drops out.

The circuit arrangement of the transistor 13 is shown in FIG. 3 only in a schematic manner. Of the Design of a suitable circuit is not within the scope of the invention and is part of the competence of normal experts.

If in addition to the timing circuit 8, other parts, such as the image signal source 2 or the detection circuit 5 are switched off, a new operating signal will not cause an automatic restart. With help of a switch 15, here as included in the operating arrangement 1, the transistor can briefly in be brought to the conductive state. The switch 15 can be designed as a push button, for example or as a second contact on a control element that is already available for other reasons.

F i g. 4 schematically shows a video circuit 20 with an image signal source and a luminance circuit as block 21. a synchronization signal circuit 22 and a mixer circuit 23 with an output 24 for a video signal modulated onto a carrier. In addition to the video circuit 20, two operating arrangements 30, 31 are coupled to the operating inputs of the image signal source 21 and at the same time with two detection circuits 32, 33 for detecting an operating action. Outputs of the same are coupled to corresponding inputs 34, 35 of an OR gate 36, of which an output 37 is coupled to an E ^: gate 38 of a timing circuit 8 with a timing signal output 9. The luminance signal at the output 40 of the luminance circuit in FIG. 21 is fed via an AND gate 42 to the mixer circuit 23 as long as the signal OTCarn output 9 of the timer circuit is "ON". In the event that a detection signal does not immediately lead to a luminance signal after a restart, due to the slowdown time of a monovibrator with a long time constant, the detection signal is fed to the AND gate 42 via an OR gate 43, if desired. However, the OR gate 43 is not essential; it is also possible to connect the output 9 of the timing circuit 8 directly to an input of the AND gate 42. It should be obvious that the AND gate 42 is the Leuchtdic'nies'.gna! locks as soon as the time signal O7 "C" becomes "OFF".

5a to 5b inclusive shows a simplified one

Time diagram for the synchronous signal (5a / the image information signal (5b). Which together as a video signal (5e) can be modulated onto a carrier by the modulation circuit 23.

F i g. 5c shows the end of a detection signal at a point in time / 1 and F i g. 5d shows the course of the OTC signal, which becomes "OFF" after a long time. This is shown briefly, in reality there are many sync pulses between fi and h. The information signal is fed to the modulator 23 up to the time (2, from the time / _ · on the AND gate 42 blocks the information signal, so that the modulator 23 only receives the synchronous signal and the picture on the display screen is now dark.

It may be desirable that the image is not completely suppressed, but rather on an image with a harmless luminance level is limited. It was found that a luminance level of about 50% of the maximum lightness level no noticeable burn-in.

An embodiment with a luminance limitation is shown in FIG. 6. An example of one Mixing circuit 23 with resistors 50, 51, 52 is indicated in a symbolic way, while the carrier modulation is not indicated for the sake of clarity. The modulator 23 operates in a manner known per se.

The AND gate 42 is through in this embodiment a protection circuit 53 has been replaced, which consists of a series circuit of a resistor 54, a adjustable resistor 55 or a diode 56 is geb.idet whose'Anode with the adjustable Resistor 55 and the cathode with the output of the OR gate 43 or directly with the output 9 the timing circuit 8 is connected.

Assuming the use of a positive supply voltage in the video circuit is the cathode the diode is normally at a positive voltage when OTC is "ON", which blocks diode 56. The luminance signal is fed to the modulator 23 via the resistor 54.

As soon as OTC goes "OFF", the diode 56 can conduct and the luminance signal is attenuated by the additional load that is created by the series connection 55, 56. It is also possible to combine the resistors 54, 55 to form an adjustable resistance potentiometer.

An output 60 of the video circuit is shown in FIG. 4 and 6 are connected to the output of the OR gate 43. If the video circuit as a whole is built into a television receiving arrangement. can the output signal of the OR gate 43 can be used to switch the receiving arrangement to television reception. If the OR gate 43 is not used, the output 60 can be connected to the output 9 of the Time circuit 8 are coupled.

F i g. 7 shows in a schematic manner that a detection circuit 71 for an operating arrangement 30 may consist of a touch contact whose generated when the operating arrangement is touched Voltage change of the timing circuit is supplied.

F i g. 8 shows a somewhat different arrangement of the elements. Two detection circuits 74 and 75 are now included in the video circuit, the inputs 76 and 77 with the outputs of the corresponding operating arrangements 30 and 31 are coupled, while the outputs 78, 79 with the Inputs 35 and 34 of the OR gate 37 are connected.

F i g. 9 shows a possible embodiment of the detection circuit 74, 75. Each of these detection circuits is provided on the input side (76 or 77) with an impedance matching 121a, b with two pairs of subsequent comparison circuits 122a, 123a and 1226, 1236, the four outputs of which have four corresponding ones Inputs of the OR gate 36 are connected.

The inputs of each pair of the two comparison circuits are connected to one another with opposite polarity, one of these connections 128a, b via a /? C element 124a, b and 125a. b is coupled to the output of the matching circuit 121a, b and the other 129a, b via an additional /? C link 126a, b and 127a, b, the total time delay between 121 and 129 being greater than that between 121 and 128 .

As soon as the input signal changes, for example at input 75 of detection circuit 74, "'ird either the comparison circuit 122a or 123a cause an output signal going "ON" and thereby temporarily make the output 37 of the OR gate 36 "ElN".

If no operation occurs, all inputs of the comparison circuits will assume the same voltage level and the output voltage of the OR gate is equal to "0".

The time constant of the /? C elements 126,127 becomes large chosen enough d. H. on the order of a minute or longer, they fulfill at the same time the task of the timer circuit 8, so that the output 37 of the OR gate 36 directly with the OR gate 43 or the UN D-Tor 42 can be connected.

The F i g. 10, 11 and 12 show embodiments for Color rendering, which incidentally corresponds to the circuit arrangements according to FIG. 4, fig. 8 and FIG. 6 fully correspond.

Now there are always three circuit breakers 42a, b, c or circuit arrangements 53a, b, c between the image signal source and the luminance circuit 200 with three outputs for R. G and B and a modulation circuit 400, for example the PAL system or the SECAM system, corresponding to the is further coupled to a synchronization signal circuit 300. An output 100 of the modulation circuit 400 can be coupled to an antenna input of a television receiving arrangement. Of course, the modulation circuit 400 can be omitted if the television reception arrangement has individual video inputs R, C and B and SYNC , as is often the case at the moment, for connecting a video recorder, among other things.

A very simple solution for color reproduction is shown in Fig. 13. The circuit breaker is here by three EXCLUSIVE-OR gates 110, 111 and 112 with outputs 113, 114 and 115, which the R-. G and ß signals deliver, and a NOR gate 116 is formed. For a simple video circuit, the color information is given with three one-bit signals SR, SG and SB , so that eight colors are determined with the respective "0" and "1" combinations, including white and black. These one-bit signals are fed to the first inputs 120, 121, 122 of the EXCLUSIVE-OR gates 110, 111 and 112, the second inputs 130, 131, 132 of which are connected together with the output 133 of the NOR gate 116. As long as this output is "0", R, G and B correspond to the values SR, Sg and SB, respectively. The OTC signal and a clock signal are fed to the inputs of the NOR gate 116. As long as OTC is "ON"

is, with normal use, the output 133 of the NOR gate 116 is "OFF". If, however, OTC becomes "OFF", 116 follows the clock signal CLK and thereby becomes "ON" and "OFF" alternately at the clock pulse of CLK. Whenever output 133 is "ON", the combination R, C and B becomes the inverse of the combination SR, SG or SB, 000 is replaced by 111, 011 di? -Ch 100 etc., so that now alternately the hue specified by SR, SO " and SB or an identical complementary hue is passed on via R, G and B. If one or more of the color signals is" 1 ", the result is alternately" 0 "and" 1 ", see above that each of the color signals has an average luminance corresponding to 50% of the maximum luminance.

This is shown, for example, for R in the time diagram from FIG. 14 on the same time axis as that from FIG. 2.

Up to the point in time t " , R remains identical to a multi-bit signal SR for the sake of clarity, with all bits of the three color luminance signals now being able to be switched as a result of OTC =" 0 ". After t " or earlier, SR no longer changes and when OTC = " 0 "appears, it remains at an amplitude a , which is high in this example. In the clock of CLK all bits are periodically and simultaneously inverted, so that periodically R now assumes the value (»max« -a),

average - »max«, which can be seen from the following:

α + {"max" - a)
2

The same is done with other shades. The pattern ultimately received remains visible on the screen but with a greatly reduced average luminance.

The clock frequency can be freely selected within wide limits. Examples are using a Second signal from a clock in the device, a 50 Hz pulse voltage derived from the mains frequency and the like

For use in a television game, Fig. 15 shows a very simple and inexpensive but still effective detection circuit. To detect the change in the position of an adjustable resistance potentiometer, the wiper 151 of which is coupled to an input 152 of the image signal source, the wiper is connected at the same time to an RC differentiating network 153, 154. The differentiated signal is fed to a pulse shaper 155, for example an OR gate, an AND gate with connected AND inputs or an inverter. This delivers a "1" pulse when the grinder is moved in the first two pulse shaper examples if the voltage taken from the resistance potentiometer rises, and in the example of the inverting pulse shaper when this voltage drops is determined, this detection pulse can be combined with that which is derived from a resistance potentiometer intended for the opponent, by combining the two signals with an OR gate 156 until the detection signal! DET, which is fed to the timing circuit 8 via the output 157 of this gate.

Since some games only have one player, such as a card game, you definitely have to then used potentiometers can be connected. Since even with two players, one player has several If you operate your own potentiometer in alternating directions times per minute, you need the second

ίο in general not necessarily with a detection circuit to be provided.

The OR gate 156 can be omitted in this case or, for example, to switch on another Actuating element like a touch contact

ι 5 can be used at an additional input 158.

Finally, Fig. 16 shows a simple timing circuit, with a digital counter circuit 160 with a counter input 161, an enable input 162 (coura enable), a reset input 163 and a counter output 164.

The counter input 161 can use the same clock signal as in FIG. 13 of, for example, 1 Hz was called to be connected.

The reset input 163 is connected to the detection output 6 of the detection circuit 5, so that the Counter circuit is brought into the "0" position by each detection signal, and then in clock speed to count. If there are no new detection signals, the counter circuit finally reaches the maximum

jo position created by decoding the counter bits is given. This can be the highest position, for example, that is caused by the "OFF" carry signal (Transmission signal) is given to the counter output 164. With a clock frequency of 1 Hz and

In a 6-bit counter, this position is reached after about 1 Minute reached if no subsequent detection signals DET appear.

In order to avoid that the counter continues counting after "1 i 1111" on the CLK to "000000", the output 164 is connected to the "count-enable" input 162 so that the counter stops as soon as CA and thus CE "OFF" However, as soon as a DET signal appears again, the counter will probably be reset. Several known digital counter circuits can be used as the counter circuit, such as a Signetics type 54 161, or two or more cascaded copies if more than 4 bits are required. The output signal CA at the counter output 164 is at the same time the time signal OTC.

If the transistor 13 from FIG. 3 is coupled to the supply unit 12 on the emitter side, the base of this transistor can be controlled with an inverter circuit which consists of a switching transistor 165 with a collector resistor 166, one end 167 of which is connected to the base of the transistor 13 As soon as OTC is "OFF", transistor 13 no longer receives base current and blocks. Normally, however, OTC is "ON", transistor 165 is conductive and transistor 13 receives a base current which is essentially determined by the size of the resistance. A restart is possible in this example in that the transistor 165 is bridged with a restart contact 168.

In addition 6 sheets of drawings

Claims (14)

IO patent claims: 1. Video circuit for processing an electrical luminance signal for playback of images on the picture tube of a display device to be coupled to the video circuit, wherein the video circuit comprises an image signal source, a luminance circuit and for prevention the burn-in of the picture tube contains a protective circuit in which a circuit breaker to complete or partial suppression of the image display is provided, and a combination of a detection circuit and a timer are provided which activate the circuit breaker, if an electrical signal fed to it remains unchanged for a certain period of time remains, characterized in that to protect the picture tube against burn-in as a result of a static image lasting longer 20th a) the electrical signal supplied to the combination (5, 8) is an operating signal that simultaneously is used to control the image information supplied by the image signal source (2), or a Signa derived therefrom! is, b) the circuit breaker of the protective circuit (11) completely or partially suppresses the output signal of the luminance circuit (3) used for image reproduction, and ^{} 0} c) the specified period in which no change is detected, in the order of magnitude a minute or more. 2. Video circuit according to claim I, characterized »characterized in that the circuit breaker (13) in one Feed conductor between an electrical feed part (12) and a feed input of the luminance circuit (3) is included (Fig. 3). 3. Video circuit according to claim 2, characterized in that a feed input of the timing circuit (8) is connected to the feed input of the luminance circuit (3) and that the video circuit is provided with a restart circuit (15) for switching on the circuit breaker (13) ⁴ ^ again . 4. Video formwork according to claim 1, characterized characterized in that the circuit breaker (13) with the luminance circuit (3) for partial or complete suppression of the luminance signal in the '° switched off state is connected in series (Fig-3). 5. Video circuit according to claim I for reproducing color images with R, G and B luminance signals corresponding luminance circuits, "characterized in that the circuit breaker R, G and ß-sub-switch (110, Ul, 112) contains the corresponding ^{Luminance signals are} essentially unchanged when the circuit breaker is switched on and the corresponding luminance signals switch periodically between the amplitudes given by the luminance circuits and the same complementary amplitudes ^{when the circuit breaker is switched off, with a complementary n =} > amplitude of the difference between the maximum and corresponds to the given amplitude (Fig. 13). 6. Video circuit according to claim 5 with digital R, G and S luminance circuits for generating luminance signals with at least one one-bit output per color tone, characterized in that the circuit breaker (110, 111, 112, 115) periodically inverts the bit outputs when switched off (F i g. 13). 7. Video circuit according to claim 1 having a carrier oscillator and a modulation circuit for feeding a video signal modjlierte on a carrier to an antenna input of a Television receiving arrangement, characterized in that the circuit breaker with the carrier oscillator is connected in series for suppressing the carrier in the switched-off state. 8. Video circuit according to one of the preceding claims with a carrier oscillator, a modulation circuit, an auxiliary antenna input and an antenna switch for supplying a a video signal modulated onto a carrier to an antenna input of a television receiving arrangement, which antenna switch in a first switching state connects the antenna input with a The output of the modulation circuit couples and in a second switching state with the auxiliary antenna input, characterized in that the antenna switch with the circuit breaker (11) is coupled, de. <in an on state puts the antenna switch in the first switching state and in a switched off state puts the antenna switch in the second switching state. 9. Video circuit according to one of the preceding claims, characterized in that the image signal source (2) is provided with at least one control input (152) for the operating signal, which with a signal input of the detection circuit for detecting changes in the operating signal is coupled (Fig. 15). 10. Video circuit according to An ^c oruch 9 with at least one touch contact for generating the operating signal, characterized in that a control signal output of the touch contact (30) is coupled to the signal input of the detection circuit (71) (Figure 7). U. Video circuit according to one of the preceding claims with at least one adjustable Resistance potentiometer for generating an adjustable analog operating signal on a Potentiometer output, characterized in that the potentiometer (150) has a signal input the detection circuit is capacitively coupled (Fig. 15). 12. Video circuit according to one of the preceding claims, characterized in that the timing circuit (8) Contains a restartable mono vibrator circuit. 13. Video circuit according to one of claims 1 to 11, characterized in that the timing circuit is comprised of a digital counter circuit (160) which is provided with a reset input (163) is provided, which forms the slarte input of the timing circuit and with an end position output (164), the forms the time signal output of the timer. 14. Television game with a video circuit according to one of the preceding claims.