DE1288117B - Television receiver with a control circuit for stabilizing an operating point of the picture tube characteristic - Google Patents

Description

1 2

In the case of television receivers, the black and on the control grid of the picture tube are a control voltage, white values of the scanned object as the maximum and the operating point in the direction of the desired or minimum values of the video signal. The value shifts, i.e. stabilizes the black value,
There is often the difficulty to keep the voltage level constant for the black level and to obtain the correct DC voltage for the beam current from the alternating current component of the image signal and from the screen of the cathode ray tube, to reproduce the black level . It is known to superimpose these DC voltages on each other and to use a control circuit to compensate for incorrect control of the sum voltage as DC voltage for the cathode ray tube through correction voltages - brightness control electrode of the picture tube and thus to keep the black level constant. io, however, the first DC voltage is supposed to regain the lost voltage, which is set by the cathode resistance of the, by the cathode resistance of the, to the reproduced voltage Picture on a picture tube caused negative feedback to adjust the upright black level again. At the 15 to be lifted today. A shift of the operating point of conventional television receivers is therefore not possible permanently on both sides with this known circuit, the setting of a contrast regulator and a brightness control. Both DC voltages influence the regulator provided. the picture tube circuit in the same direction.

The invention is based on the object of providing an It is also known (German Auslegeschrift

To create a television receiver without a brightness regulator, 20 1 065 454), the direct voltage for the brightness

at which the black level is always out of the picture tube even with the aging display control electrode

voltages, changes in operating voltage, etc. to divert a constant beam current if there is a black in the image

is held. Pixel occurs. Apart from the fact that not in

The invention consists in a television receiver having a black pixel for each picture

with a control circuit to stabilize a 25 must and that the DC voltage for the brightness

predetermined operating point on the control characteristic curve of the control electrode of the duration of the eventual

the picture tube is dependent on aging, changes in the black pixels that occur,

Operating voltages, etc., which is marked, only a radiant

due to the simultaneous application of the following, partly current-dependent control voltage used, while-

Features known per se: 30 rend from the video signal or its AC voltage component a yes / no information (black

a) From the alternating current component of the picture tube _{value or} _ _no black level) is obtained. A controlling video signal is obtained through constant and continuous readjustment of the operating point, also in the direction of a _{DC voltage that is value-dependent on black or ultra-black for} video signals that do not contain a black value; _{35 is not possible} .

b) the direct voltage is applied to a control electrode. To explain the invention, the following the picture tube fed with such a control direction, several embodiments on the basis of the drawing that the operating point is described on the control characteristic.

is shifted in the same sense as by the In F i g. 1 is the block diagram of the kinescope controlling video signal; ⁴ ° circuit of a television receiver shown at

the video signal 1 from the output of a video

c) from the voltage drop of the beam current of the amplifier 2, on the one hand, the picture tube 3 and the other picture tube, a further control DC voltage _se j _{ts is obtained} via a capacitor 4 of a rectifier; circuit 5 for obtaining a regular DC voltage

d) the further control DC voltage, the control ⁴⁵ ^ f ^_1/7 is * ¹ T supplied supplied to ^{the SC} ^ T ° Ä ^Ultras f ™ ^arzw ^ electrode of the picture tube with such control direction of the alternating current proportion of the video signal 1, that the operating point on the control - ™ F ^d · ^the beam current / _{S (r} picture tube 3 is of a characteristic curve in the opposite direction shifted circuit 6 for obtaining a further strahlben is as indicated by the first control voltage; supplied current dependent "control voltage U _R2 Die!.

50 control DC voltages Ur _x and Ur _{2 are thus obtained}

e) the magnitude of the two control DC voltages is such that both voltages correspond to one value, dimensioned so that in the normal working range of the distance of the AC axis of the video circuit the shifts in the operating point signal from the respective black or ultra black to corresponds to the control characteristic through the control equivalent, but both voltages are constrained have just been lifted. 55 other are opposed. For the set

adjustable black level on the control characteristic of the

The operating point on the control characteristic curve is therefore the picture tube 3, therefore the voltages of the units 5 and 6, initially set to the desired value, cancel each other when they are superimposed in an addition and control DC voltages on the beam current circuit 7. In this case, and the rectification value of the video signal, the operating point of the picture tube 3 is superimposed by the resulting one with such a magnitude that there is no change in voltage U. However, as soon as one of the straight against each other cancel. This state will change control voltages, be it due to aging, as long as the video signal has the same composition as the video signal written by the transmitter or the operating voltages supplied by a deterioration, so the control voltage will have the desired size and the tubes will still have 65 for the Picture tube changed and thus the black has not aged. As soon as these values change, worth it. On the way over the jet stream is z. B. the picture tube has aged, however, changes to a span ratio of the two control voltages that counteracts this change. This creates voltage.

3 4

Like F i g. 2 shows, the one corrected by the beam changes corresponds to that in a change

current obtained control voltage that exist by equal to the pulse size, as in this circuit

direction obtained control voltage, because the black a rectification after the ultra black value

or ultra black value of the video signal on the (sync pulse peak) is made.

Control characteristic of the picture tube is kept constant. 5 A circuit in which this disadvantage is avoided

In Fig. 3 is a detailed circuit of FIG. 1 and also the control steepness is improved, which in

shown, in which the video signal 1 from the anode of the circuit of FIG. 3 still through the

derived from a video amplifier tube 10 and dependent on the maximum stroke of the control voltage

a voltage divider 11, 12 and a capacitor 4 from the operating voltage of the control tube and its

the anode of a diode 13 is supplied. The diode 13 io controllability is determined in FIG. 4 descriptive

is connected to earth with the cathode and thus generates the circuit elements in this circuit are identical

Load resistor 14 a DC voltage, which as in the previous figures with the same reference

provided with the peak value of the positive half-wave of the variable sign.

Current component of the video signal 1 is dependent. As shown in FIG. 3 the video signal from the anode is obtained via a 15 of the video amplifier tube 10 via a voltage resistor 15 on the control grid of an amplifier tube divider 11, 12 and derived via a capacitor 4 16, whose anode is fed via a potentiometer 17 to a rectifier 13. This aligns the adjustment of the operating point of the brightness and a signal, but not pulses corresponding to the tip of the synchronous resistor 18 connected to the operating voltage U ₃ , but gains an equal control. The wiper 19 of the potentiometer 17 is over 20 voltage, which depends on the black level. For this purpose a resistor 20 and a resistor 21, the sync pulse is blanked, as connected to the control grid (Wehnelt) of a cathode ray connection point of the resistors 11 and 12, the cathode of which the video signal 1 is interpreted. For this purpose, the voltage is applied to the base point. The beam current of the cathode ray splitter 11, 12, a negative return pulse from the tube 22, flows via the high-voltage electrode, which is fed to the 25 line output stage (not shown), which is deformed by the high-voltage line 23, the high-voltage DC circuit 34, in such a way that it is used for a rectifier 24 and the high voltage winding 25 and blanking required phase position and amplitude from there via resistors 26, 27 and 20 as well as the receives. The DC control voltage Ur ₁ is grounded by a source U _B. The beam current is amplified by triode 16, which is formed here by a system of the aid of a separating capacitor 28 from the double triode. The input circuit is low-voltage winding 29 of the flyback transformer between the control grid and the cathode. The regular gates 30 kept away. A screening of the DC voltage is done by the cathode resistor 35 of these conditions by capacitors 31 and 32. Taken from the tube and on the one hand the control grid point 33 in the control grid circle of the cathode ray tube of a further amplifier tube 36 and on the other hand 22 a resulting voltage is in this way, 35 of the cathode the picture tube 22 supplied. In addition to the two control DC voltages and control DC voltage, the cathode of the picture tube is composed of the basic operating voltage, with the predetermined operating point precisely set via a capacitor 37 without direct current value. The capacitive DC control voltages cancel each other out. The cathode coupling of the picture tube is a tube 16 used to amplify the negative black level errors generated by 40 undesired, rectification of the AC voltage component of the video which is not dependent on the beam current and the effect of the control DC voltage obtained. In addition, readjustment of a positive black level error causes this amplifier tube to reverse the phase. By the voltage drop at the cathode of this DC voltage. resistance 38, 39 of the picture tube continues to arise

The control process would proceed roughly as follows: 45 negative black level error dependent on the beam current. In the case of a white image and high contrast, the greater the cathode resistor rectifier 13, the greater the maximum negative control voltage. Because the cathode resistance generates the voltage. It can be so large that the picture tube is connected to the cathode of the first triode 16 and is just blocked. The anode voltage is the positive image content-dependent black level tube 16 and thus the voltage of the Wehnelt error and the negative beam current-dependent black cylinder is therefore maximally positive. As a result, value errors connected in series. When the Süahlstrom reaches its maximum, these control variables are also dimensioned in such a way that the black value is negative despite the capacitive value and at the base of the high-voltage coupling of the picture tube independent of the picture content. To do this, however, it is necessary that the regulating voltage. The image content-dependent rule equal gain is adequately dimensioned. For this voltage Ur ₁ is limited by the control area of the tube 16, a voltage is limited at the cathode resistor, and the beam current-dependent voltage Ur _{2 is} tapped and amplified in the triode 36, which is due to the dimensioning of the resistor 20 of the partial readjustment in the cathode chosen so large that the Wehnelt voltage does not change in the case of essentially only the image content fluctuations under image content changes. The black 60 lies. The circuit can be dimensioned in such a way that the transfer of values remains unadulterated. Changes that the triode 36 only acts as an amplifier for the asymmetry but the beam current without changing the metry of the compensation circuit. You can video control voltage, e.g. B. by aging of the cable but also be designed so that the triode and its cathode ray tube, then causing the changed circuit are part of the compensation circuit. The beam current-dependent control voltage, a counter-circuit arrangement shown, has the advantage of coupling and compensates for the error within the framework of the already slight differences between the two control steepnesses that are present. In the case of the superimposed voltages described as a large control voltage, any changes that are further amplified will not have an effect. the

Claims (13)

5 6 The steepness of the control becomes very large and there is one to be exploited. These pulses are to be fed into the very good stabilization of the preselected brightness anode circuit of this diode,
value possible. The black level transmission can F i g. FIG. 6 shows a circuit which turns out to be particularly precise or with deliberate errors, both advantageously for keeping the black negative constant and in the positive direction. 5 value, ie for automatic brightness control In Fig. 5 is shown a circuit which has been proven by. The some changes containing the black level compared to the switching according to the video signal is detected by the anode of the video output tube 10 FIG. 4 is improved. In this circuit, too, circuit elements identical to the rectifier 13 are provided with the same reference numerals via the voltage divider 11, 12 to obtain a control which is dependent on the image content. The voltage is generally supplied in the receiver and the cathode fading control via the capacitor 37 is fed to the picture tube 22 by means of a keyed control. The anode of the DC acting on the ultra black value, ie the tip judge 13 are scanned by the line output stage Tastder sync pulses. In the case of such a control pulse 42 with such a phase position and formation, it is often important, in the case of a contrast control, that the control voltage readjust the brightness from the black level. In Fig. 5 it happens 15 is dependent. The amplitude of the probe pulses 42 is stabilized by the fact that the negative fluctuations which are present at the control grid of the tube 36 and are used to regulate the potential by an NTC resistor 43 against temperature. The limitation of the impulse roof, which is necessary for the deformation of the tension on the setting of the contrast regulator, is made dependent. In this way, each running impulse can occur through a member 44. The control voltage obtained in this way to adjust the brightness at any time in the case of contrast will be achieved by a triode 16 change. Furthermore, this is done, at the anode of which the amplified control span circuit means are used to remove the preselected voltage Ur ₁ . This black level control voltage, even in the event of mains voltage fluctuations, now reaches the cathode of the picture tube 22 and changes in the deflection part are kept constant. and on the other hand to the control grid of the amplifier - this includes the cathode voltage for the tube 36. The compensation circuit in the picture tube 22 of the booster voltage of the line essentially corresponds to that in FIG. 5 circuit shown, deflection transformer is derived. Furthermore, a capacitor 41 is switched from the operating voltage source to control the fading control voltage from the line deflection transmission grid of the tube 36, a voltage is fed to the on-30 die circuit according to FIG. 6 has the advantage that a flow of the deformed probe pulses at the anode can be canceled in the circuits described above. Compared to F i g. 4, the tube 36 is capacitively bridged between the influence of the rectifier efficiency of the DC grid and the anode. This avoids the judge 13 by utilizing this tube for alternating voltages strongly against the characteristic curve kink of the tube 16. This is coupled so that any risk of self-excitation 35 replacing the peak rectification with a keying is eliminated and the brightness decays into the porch. One could be flattened the Einstark. Such decay processes flow through the rectifier efficiency are often caused when the control slope is too steep to avoid using a VDR resistor. Any remnants of such a thing that may still be present can be removed instead of being touched into the porcelain shoulder, as in decay processes, 40 FIG. 6 indicated, you can also perform a keying by the time constants at the cathode and Wehnelt - the black shoulder. In this case, however, the cylinder of the picture tube would have to be appropriately matched to the amplifier 16 without being phased. The circuit described so far has to work in reverse. Likewise, this keying could still have the advantage that the luminous point can also be carried out at the anode of the triode 16 when the carrier, failure or shutdown of the device automatically 45 z. B. is limited by using a phase shifted. This is caused by the impulse. Here, too, the keying would be carried out on the one hand, the video signal of the picture tube via a porcelain shoulder,
capacitive coupling is supplied and that other on the other hand, the triode 36 through the capacitor 46 in the claims: Switching off the device is locked. About this 5 ° 1st television receiver with a control circuit The capacitor is the negative switching surge to stabilize a predetermined working the positive operating voltage to the grid over-point on the control characteristic of the picture tube wear. In addition, this circuit provides an anti-aging, changes in the operating voltage Beam current limitation by the capacitive voltages, etc., characterized by Coupling of the picture tube and the capacitive coupling 55 the simultaneous use of the following, in part of the picture content-dependent rectifier circuit with known features: Carrier failure a value is returned that the _ AC axis of the video signal. ^{a> From de} f AC part of the picture tube From so far described circuit controlling video signal 60 is ^ric _u ^htun g a compensated by DC fluctuations of the synchronous level or their inputs largely from black or Ultrafluß to the black level, black level abhangige DC voltage (Ur ₁₎ by the white balance changes, and the black won; value remains almost constant. A change in b) the direct voltage (Ur ₁ ) becomes a control synchronous level would in this case not cause a contrast electrode of the picture tube with such a control change. In some cases it can be supplied to the device that the operating point can also be used to blank out the image sync pulse before the control characteristic in the same sense as vef peak rectification. To deform, the rectifier diode 13 can also signal; c) a further control DC voltage (Ur ₂ ) is obtained from the voltage drop in the beam current of the picture tube; d) the further DC control voltage (Ur ₂ ) is fed to the control electrode of the picture tube in such a control direction that the operating point on the control characteristic is shifted in the opposite direction as by the first DC control voltage; IO e) the size of the two control DC voltages is dimensioned so that in the normal working range the shifting of the operating point on the control characteristic the control DC voltages have just been canceled. 2. Television receiver according to claim 1, characterized in that the control voltage from the AC component is obtained by peak rectification (Fig. 3, 4, 5). 3. Television receiver according to claim 1, characterized in that the control voltage from the alternating current component obtained by sampling for the black or ultra-black value (FIG. 6) will. 4. Television receiver according to claim 1 to 3, characterized in that an amplifier (16, 36) is provided to amplify the DC control voltage (Figs. 3, 4, 5, 6). 5. Television receiver according to claim 1, characterized in that the beam current-dependent control DC voltage (Ur ₂ ) is tapped off at a resistor (17, 18, 20) lying in series with the high-voltage winding (25) of the line deflection transformer (30) (F i g. 3) . 6. Television receiver according to claim 1, characterized in that the beam current-dependent Voltage at a resistor (35, 38, 39) switched on in the cathode circuit of the picture tube (22) is tapped (Fig. 4, 5). 7. Television receiver according to claim 5 or 6, characterized in that the resistor is at least partially in the circuit of the amplifier (16). 8. Television receiver according to claim 7, characterized in that the resistor (35) in the circuit of the amplifier (16). 9. Television receiver according to claim 1 to 8, characterized in that the _{direct voltage resulting from the superposition of the control voltage (17B 1} , Ur ₂ ) is fed to the picture tube via an amplifier (36). 10. Television receiver according to claim 9, characterized in that the grid-anode path of the amplifier (36) is bridged by a capacitor. 11. Television receiver according to claim 2, characterized in that to achieve one of the Black level dependent DC voltage to the video signal (1) a pulse to blank the Sync pulse is superimposed. 12. Television receiver according to claim 11, characterized in that the pulse is a means a distortion circuit (34) is deformed return pulse. 13. Television receiver according to claim 3, characterized in that from the return pulse by limiting an impulse is obtained, the roof of which has such a slope, that the impulse gropes into the black shoulder at great width. For this purpose 2 sheets of drawings 909 505/1385