DE2816224A1 - SCREEN CORRECTION - Google Patents

Description

Screen correction circuit

The invention relates to a correction circuit which is suitable for correcting raster distortions in a television viewing device.

A switched pincushion correction circuit is disclosed in U.S. patent application No. 722,600 of September 13, 1976 by the same inventor and there is a switched impedance in Row with the horizontal deflection winding. The switch is activated at a time during the second half of the horizontal retrace interval closed, i.e. conductive, and remains during the remaining part of the horizontal retrace interval and for the entire subsequent outward run interval conducting. A switching control circuit changes the switching time during the horizontal retrace interval progressively in the course of the vertical scanning interval. The ratio of the times during which the switch is switched on and switched off during the return interval changes the effective or mean impedance, which in Row with the horizontal deflection winding lies. As the active time changes, the time also changes mean impedance with the vertical frequency in series with the horizontal deflection winding. For the pillow correction is the mean impedance in series with the horizontal deflection winding at the top and bottom of the vertical deflection relatively high and relatively low in the middle of the vertical deflection.

It is now common to use other circuit parts of a television receiver to be supplied from the horizontal deflection circuit. For example, at the output of the horizontal deflection generator often a rectifier and a filter circuit are coupled to which, in turn, a load, such as the picture tube end anode or a sound or video amplifier, which is

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zontalgenerator derived energy are fed. A switched synchronous vertical deflection circuit can also be used from the horizontal deflection circuit according to the same inventor's US Pat. No. 4,048,544. One must expect that such Loads change during their operation. This changes the load caused by the vertical deflection circuit just mentioned periodically with the vertical deflection frequency. The loading of the picture tube end anode and the sound channel do not change periodically in accordance with the information content. With both types of load, the width decreases as the load increases the horizontal retrace pulses.

This load-dependent reduction in the width of the horizontal pulses leads to a lateral modulation of the grid, which leads to the usual lateral pillow distortion is added. The loading of the horizontal deflection generator by a switched vertical deflection circuit results in periodic raster distortions which are generally of the appearance of barrel distortions while Loads that change without comparable dependencies result in more unpredictable types of raster distortion to have. When using the aforementioned switched pillow correction circuit, these undesirable distortions arise because the ratio of the switch-on time to the switch-off time of the switch changes with changes in the horizontal return pulse duration .

In a preferred embodiment of the one to be described here Invention includes a raster correction circuit for a television deflection circuit for a horizontal deflection current generator Generation of horizontal frequency deflection signals, and a horizontal deflection winding is coupled to this generator, which generates recurring return pulses as a result of these deflection signals. A load circuit is connected to an output of the Horizontal deflection generator switched and is fed by this. Call changes to the load by this load circuit Changes in the duration of the return pulses, whereby raster

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distortions arise. A pulse duration sensing arrangement is coupled to the horizontal deflection current generator, which is a Control signal generated that is a measure of the duration of the return pulses. With an output of the horizontal deflection current generator and with the sensing arrangement for the return pulse duration, a controllable impedance is further coupled, which is below the Influence of the control signal compensates for raster distortion.

The invention is explained in more detail below on the basis of an exemplary embodiment illustrated in the drawings. Show it:

Fig. 1 is a circuit diagram, partially in block form, of a television deflection circuit in accordance with the invention and

Figures 2 and 3 are voltage and current waveforms for illustration the mode of operation of the circuit shown in FIG.

According to the upper and right-hand part of FIG. 1, a deflection current generator feeds 24 a flyback capacitor 13 and a horizontal deflection winding 26 via a series capacitor 28, which the S-shape is used. The horizontal deflection current generator 24 also feeds the primary winding 55 a of a flyback transformer 55. A secondary winding 55b of transformer 55 supplies power to a switched one during the horizontal retrace interval Synchronous vertical deflection circuit 22, which in turn generates a vertical frequency deflection current through a vertical deflection winding 23 lets flow. The vertical deflection circuit acts as a variable load for the horizontal deflection generator. Another variable load 58 loads transformer 55 during horizontal retrace. A second secondary winding 55c of the Transformer 55 supplies horizontal flyback pulses 35 according to sketch 34 to a voltage regulating circuit in a periodic sequence 56, which between an operating voltage source B + and the gene-

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rator 24 is provided. The control circuit 56 can be of a known type for controlling the peak amplitude of the flyback pulses Be 35.

The horizontal deflection winding 26 is in series with an impedance circuit 31, which contains an inductor 32 and a capacitor 36. The capacitor 36 is made using one in both Direction of conductive switch 40, which contains a thyristor or SCR 44 with diode 42 connected in anti-parallel, periodically connected in parallel with inductance 32.

The switch 40 is controlled by strobe pulses 50 which are sent to the control electrode of the thyristor 44 by a switch control circuit 46 are fed. This circuit 46 contains a comparison circuit in the form of a differential amplifier 100 first and second emitter-coupled transistors 102 and 104, respectively. The interconnected emitters of these two Transistors are grounded through a resistor 128. The base of transistor 102 is connected via node 152 A DC reference voltage is supplied from a voltage divider, which has a resistor 142 and an adjustable grid width adjuster serving resistor 138 contains. Furthermore, the base of the transistor 102 is supplied by a vertical parabola generator 110 a vertical frequency parabolic voltage 136 is supplied. With the help of an adjustable one belonging to this generator Resistance 114 can be used to adjust the amount of lateral pincushion correction Set via the size of the parabolic oscillation 136.

The base of a transistor 104 will be from the second secondary winding 55c horizontal frequency return pulses 35 are supplied via a diode 118 and a resistor 120. The base of transistor 104 is also through a resistor 126, the is responsible for the formation of a base pulse, to a sawtooth shaping capacitor 122 and a charging resistor 124 connected.

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The output of the differential amplifier 100 is from the collector of transistor 104 through an inverting amplifier including transistor 132, resistors 106, 108 and 109 and a capacitor 105 removed. This capacitor integrates the signals fed to the control electrode of the SCR 44 capacitive coupling from the anode, so that the sensitivity of the SCR to triggering by a rapidly changing anode voltage is reduced.

A trapezoidal correction of the grid is carried out with the help of a potentiometer 144 connected between a source of vertical frequency sawtooth vibrations and ground, along with a coupling capacitor 148, which is the tap of the potentiometer 144 with the tap of a voltage divider made of resistors 115 and 146, which are connected across the sawtooth shaping capacitor 22, connects.

In operation, the voltage supplied by the secondary winding 55c becomes slightly negative during the horizontal trace interval, and diode 118 allows a constant current through the resistors 120 and 126 flow, so that the transistor 104 is blocked and the transistor 102 is kept conductive and the capacitor 122 discharges. The transistor 102 conducts because of the bias voltage caused by the resistor 128. When locked No voltage appears at resistor 106 at transistor 104, so that transistor 132 is blocked and therefore the thyristor 44 does not switch on.

During the horizontal retrace interval, positively directed Voltage pulses to the cathode of diode 118 and block these. As a result, the discharge branch for the capacitor 122 is released, so that this is in accordance with the curve shape 134 begins to load. The constant current flow through the resistors 120 and 126 also ends when the diode 118, and the base voltage of the transistor 104 rises abruptly and forms a pedestal voltage. Every single voltage pulse 134

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- Q -

consists of a base, which, as said, is caused by the resistor 126, and a superimposed ramp section, the is caused by the charging of the capacitor 122 via the resistor 124. At the end of the retrace interval, the transformer brings 55 the diode 118 to conduct again, so that the capacitor 122 is on the through the resistors 120, 124 and 126 discharge certain voltage.

The vertical frequency component of the parabolic voltage remains in operation 136 the reference voltage at point 152 is practically constant. The ramp portion of the repetitive oscillation 134 is more negative than the reference voltage at point 152 at the beginning of the Horizontal retrace interval, but it increases, becomes equal to and exceeds the reference voltage. When the vibration 134 is more positive than the reference voltage, the transistor becomes 104 conducts and supplies an output pulse to the thyristor 44 via the transistor 132. The most negative part of the Parabolic stress 136 occurs in the middle of the vertical deflection. The parabolic and sawtooth voltage therefore intersect - So they reach the same voltage value - and there is a switch-on pulse 50 at a point in time that is opposite to the Horizontal retrace pulses in the middle of the vertical deflection is shifted furthest forward. At the top and bottom At the end of the vertical deflection, the parabolic voltage 136 is most positive and intersects the oscillation 134 relatively late during the return pulse, so that a switch-on pulse 50 is generated of a relatively short duration.

When switch 40 is opened, the entire impedance appears the inductance 32 in series with the deflection winding 26. If the switch 40 is closed, however, then appears in series low impedance with the deflection winding. The leading edge of each of the switch-on pulses 50 switches the thyristor 44 on at any time during the horizontal retrace interval. By controlling the length of time during the horizontal retrace interval, during which the switch 40 is switched on

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_{if f} , the mean or effective impedance, which is in line with the deflection winding, can be determined. As a result, the magnitude of the current in the deflection winding 26 at the beginning of the horizontal deflection interval, and thus the deflection amplitude, can be controlled.

The explained time modulation of the leading edge of the pulses 50 modulates the in series with the deflection winding lying mean impedance. When the leading edge of the pulse 50 appears late, then switch 40 also closes late, and the mean impedance is high. If on the other hand kicks the front flank the switch-on pulse 50 occurs relatively early during the horizontal retrace interval, as in the middle of the vertical deflection, then the mean impedance in series with the deflection winding is small and a relatively large deflection current flows. So far as described so far, the circuit is similar to that described in the referenced U.S. Patent Application No. 722,600.

As already indicated, the load on the horizontal deflection generator by the switched vertical deflection circuit 22 a shortening of the duration of the horizontal flyback voltage pulses result, because during the return interval of the return condenser 13 contained resonance circuit energy is withdrawn. This becomes easier to understand when you consider that in the middle of the horizontal retrace interval, the entire return energy is stored as a voltage in the capacitor 13. During the last half of the horizontal retrace interval, the energy becomes inductive in a resonance oscillation Components of the deflection circuit transferred. The energy removed here has the consequence that the voltage of the return condenser drops faster than when there is no load.

2a shows part of a return oscillation 34 of the return pulses 35 to illustrate the duration modulation. If there is no load, the representation of the return voltage pulses applies corresponding to the common boundary line 210 and the

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Line 212. In the loaded state is the duration of the return pulses smaller, and the illustration of lines 210 and 214 applies. The trace interval voltage is negative compared to the mean value and is represented by line 216. On an oscilloscope one can see that dLe is the trace interval voltage line 216 is thickened, and this shows the effect of the vertical frequency modulation. This modulation arises as a result of changes in the mean value of the oscillation 34 as a result of the pulse duration modulation.

The voltage control feedback loop with controller 56 senses the amplitude of pulses 35; usually she responds to the peak value of the flyback pulses and regulates to a constant flyback voltage amplitude for the ultor voltage and the image width stabilization. The trace voltage amplitude is in a fixed ratio to the return voltage amplitude, which depends on the return duration. The controller 56 therefore holds the return pulses at a constant amplitude, but corrected he does not change the return pulse duration, which Lead to voltage changes.

Fig. 2b shows repetitive voltage pulses 134 which occur at the base of the transistor 104 and each a socket and have a ramp portion 222. These two parts begin simultaneously at time T1 at the beginning of the outgoing interval. The ramp section 222 intersects a reference voltage 220 at the point in time T3. A switch-on pulse brings about this point in time the switch 40 to conduct, and in the deflection winding 26 a current begins to rise rapidly. The ramp portion 222 ends before the end of the retrace interval, and that by the resistance 126 conditional socket also ends. From Fig. 2b it can be seen that the increase in the current in the deflection winding in the case of a weak load on the return pulses, the time available from T3 to T5 is sufficient. When the return pulses on the other hand, are heavily loaded, corresponding to the flank 214 in FIG. 2a, then that is sufficient to increase the current in the deflection winding

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available time only from T3 to T4. Thus, a heavy load causes the effective impedance of the pillow correction impedance circuit to increase .

The load on the horizontal deflection generator from the vertical deflection circuit tends to be maximum at the top and bottom of the vertical deflection interval because of that of the vertical deflection circuit supplied current is then maximum. Such heavy load on the top and bottom of the vertical deflection interval reduces the horizontal deflection current in the manner described. Fig. 3a shows the horizontal deflection current and its Envelope 308 in the course of the vertical deflection interval, with the maximum load at points 310 and 314 accordingly the upper and lower ends of the vertical deflection interval is maximum. In the area 312 is the horizontal deflection because of the lower loading by the vertical deflection circuit. The envelope 308 causes a mustache-shaped lateral raster distortion. The vertical deflection circuit can be switched off Reasons that are related to a linearity improvement, are operated "overlapping", the not for the vertical deflection required energy is destroyed, especially in the middle of the vertical deflection interval. This results in a larger, but more constant load on the horizontal deflection generator and thus a reduced horizontal deflection current, as illustrated by envelope 316. Other variable loads for the horizontal deflection current generator, such as they are illustrated by the block 58, for example, lead to distortions of other shapes that do not correspond to the vertical frequency are periodic.

To correct one caused by the return duration modulation Raster distortion, a flyback pulse duration sensing circuit 60 (Fig. 1) is used, which is one of the flyback pulse duration Corresponding DC voltage generated and the base of the transistor 104 to correct the caused by the permanent modulation Raster distortion supplies. The sensing circuit 60 is

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holds a capacitor 64, connected through a diode 62, to the one Resistor 66 is in parallel, connected to the anode of diode 118 is. In series with the diode 62 there is also a resistor 68 which, together with the capacitor 64, forms an integrating element forms, which is coupled to the trace interval voltage appearing on the secondary winding 55c. Because the peak of the pulse 34 remains constant, but the pulse duration changes, the trace interval voltage also changes with respect to Dimensions. As the retrace pulse duration becomes shorter, the trace interval voltage becomes less negative. During the trace interval capacitor 64 integrates the trace interval voltage. During the return interval, locked Diodes 62 and 118 feed the integrated voltage from capacitor 64 to differential amplifier 100 when the capacitor 64 discharges through resistors 66, 120 and 126. With increasing load on the horizontal deflection generator and decreasing Pulse width charges the capacitor 64 to a less negative or more positive voltage. This tension is shown in Fig. 3b for the case of a switched synchronous vertical deflection circuit. The one generated by the sensing circuit 60 Control signal is shown as waveform 340 which is most positive at the top and bottom of the vertical deflection and is most negative in the middle of the distraction. In the "overlap" mode of operation of this vertical deflection circuit, which gives a constant heavy load, the control signal is even more positive and during the vertical interval constant as line 342 shows.

The control signal generated by the sensing circuit 60 adds to the ramp portion 222 of the pulses 134 applied to the base of transistor 104 appear. When the load is higher, the control signal becomes more positive and triggers the comparison circuit earlier in the retrace interval during each repeating cycle. This will put the in series with the horizontal deflection winding lying mean impedance is reduced, so that the deflection current is increased in such a way that current changes

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-14- is counteracted as a result of the return duration modulation.

That of the sensing circuit 60 when loaded by the vertical deflection circuit The generated control signal corrects the mustache distortion caused by the pulse width modulation. the However, the pillow correction circuit continues to correct at the same time the vertical frequency parabolic raster distortion caused by the picture tube geometry due to the vertical frequency change the reference voltage at point 152 with parabola 136. Thus, the pillow correction is retained and is with respect to their size can be adjusted with the aid of the resistor 114.

Albeit here a switched pillow correction circuit for the purpose of explanation has been discussed, deflection current modulation is always obtained with modulation of the return pulses by a load such as load 58 due to changes in the resonance conditions for deflection winding and Return condenser. This modulation is achieved by a return pulse duration sensing circuit and corrects a controllable impedance which is switched to counter the deflection current changes.

It will be understood by those skilled in the art that the invention can also be implemented in other embodiments. For example could the sensing circuit for the duration of the return pulse also integrate the return interval pulses instead of the trace interval pulses.

The invention described above makes the horizontal deflection current essentially independent of the load on the horizontal deflection generator and makes a deflection and pincushion correction circuit such as that shown in Figure 1 virtually independent of overlap settings the switched synchronous vertical deflection circuit. The circuit according to the invention also corrects jagged Grid pages, as shown by strong video modulation, such as a horizontal white stripe or a gray grid,

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caused, in turn, by the load on the picture tube dependent pulse duration changes is caused. Further the bends at the top and bottom of vertical lines with variations in brightness are improved. The inventive Arrangement also corrects load fluctuations that are caused by driver circuits for quadrupole windings. Such load fluctuations can be a raster width modulation in the area of the middle of the vertical deflection interval.

Some circuit parameters relating to FIG. 1 with which good results have been achieved are given below:

Waveform 34 Condensers 64

105

122

Resistors 66

68 106 108 109 115 120 124 126 128 138 142 146

^55V ss 0.05yF 4700 pF 3300 pF 8.2kfi 1kfl

2.2kfi 33Ω

4, TkO

2.2ki2 2.2 4.7kfi 47kn

8Ü98A3 / 0791

Claims (10)

RCA 71872 / Sch / Vu Brit Notes No. 15545/77 dated April 14, 1977 'Dr. Dfe ^ r ν. Berold ' USSN 830854 ν. Sept. 6, 1977 Dipi.-h- \ Ρ- uchäz Dipl. «·! -;:. Woirörrg Heus! © r 8 Munich öa, P.O. Box 860688 RCA Corporation, New York, N.Y. (V.St.A.) Claims (i) / Screen correction circuit for a television deflection circuit with a horizontal deflection current generator for generating horizontal frequency deflection signals to which a horizontal deflection winding is connected, which generates recurring return pulses due to the deflection signals, with one to one Output of the Horizontalablenkstromgenerators coupled and fed by this sensing circuit, which by changing the Load the duration of the return pulses in a raster distortion effecting manner changed, characterized in that with the Horizontalablenkstromgenerator (24) a sensing circuit (60) is coupled for the duration of the return pulse, which is one of the return pulse duration corresponding control signal generated, and that a controllable impedance (32,36,40,42,44) with an output of the horizontal deflection current generator (24) and is coupled to the sensing circuit (60) for the return pulse duration, which is under control the raster distortion is compensated by the control signal. 809843/079 1 2) Raster correction circuit according to claim 1, characterized in that the controllable impedance (32,36,40,42,44) is controlled by a pillow correction circuit. 3) raster correction circuit according to claim 2, characterized in that that the controllable impedance one with the horizontal deflection winding (26) interconnected impedance (32) and one with this interconnected controllable switch (44) and a control circuit (100,132) for the switch contains which is coupled to the horizontal deflection current generator (24) and the controllable switch (44) and the controllable switch during controls the recurring return pulses and the reaction of the horizontal deflection winding (26) to the deflection signals influenced in the sense of a correction of the raster distortions. 4) raster correction circuit according to one of claims 1 to 3, characterized in that the sensing circuit (60) for the Return pulse duration includes an integrator (64) coupled to the horizontal deflection current generator. 5) raster correction circuit according to claim 4, characterized in that that the integrating element is connected to the horizontal deflection generator via an arrangement (62, 118) which conducts current only in one direction is coupled. 6) raster correction circuit according to claim 4, characterized in that that the sensing circuit for the return pulse duration is a first and a second only conductive in one direction Element (62 or 118) for coupling the integrator (64) to the horizontal deflection current generator during a first section each horizontal deflection cycle and for decoupling the integrator from the horizontal deflection current generator during a second portion of each horizontal deflection cycle and that the integrating member (64) with the controllable Impedance (32,36,40,42,44) via a first coupling arrangement (66) 809843/0791 is coupled to change the controllable impedance in the sense of a correction of the raster distortion. 7) raster correction circuit according to claim 4, characterized in that that the integrating element has a capacitive element (64) connected in series with a resistor (68). 8) raster correction circuit according to claim 7, characterized in that that the resistor (68) with the Horizontalablenkstromgenerator via the series connection of the first only in a direction electrically conductive element (62) is coupled and that the capacitive element (64) via a second resistor (66) is coupled to the controllable impedance. 9) raster correction circuit according to claim 8, characterized in that that the resistor (66) is connected at a first end to the capacitive element (64). 10) raster correction circuit according to claim 9, characterized in that that the first only in one direction current-conducting element (62) in series with the second only in one direction conductive element (118) is connected and that the second resistor (66) with the end facing away from the first end on the connection point of the first and the second only in one direction current-conducting element (62 or 118) connected is. 809843/0791