FI62918C - KORREKTIONSKRETS FOER OEST-VAESTRIKTAD DYNEDISTORTION - Google Patents

Description

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NtW »Odi mlmmywlwii '' AmMu» iiclagd «ch« publicβη public ·· *! χ1 ϋ? (32) (33) (31) «uoiiMut-BnM pHorit * 18 q1 | γ1 (USA) i462058 (71) RCA Corporation, 30 Rockefeller Plaza, New York, NY, USA (72) Wolfgang Friedrich Wilhelm Dietz, New Hope, Pennsylvania, USA (7 * 0 0y Kolster Ah The present invention relates to a cushion distortion correction circuit for use in display systems, such as television systems, for example, in the field of television.

It is known per se that the geometric dependence of the scanning beam or rays on the cathode ray tube with respect to the inner surface of the image surface along which the rays are scanned causes a distortion of the raster, known as pad distortion. This distortion is characterized by the horizontal expansion of the image at the top and bottom of the raster compared to the centerline of this raster. It is also known per se that in many situations this distortion can be corrected by modulating the horizontal sweep current at the vertical deflection sweep frequency. Often, this modulation is in the form of a parabolic that produces the largest decrease in the horizontal scan current at the top and bottom of this raster, which corresponds to the beginning and end portions of the vertical plot time compared to the horizontal scan current in the center of this raster.

2 62918

The vertical sweep frequency modulation can be adapted to the horizontal sweep current in a number of different ways. A particular circuit section can be placed in a circuit with horizontal deflection windings and adjusted by varying the impedance for the horizontal sweep current according to the vertical frequency. A transformer in the same circuit as the horizontal deflection windings can also be used to implement the necessary modulation. A slightly more modern way is to rectify the horizontal frequency energy obtained from the winding from the horizontal output transformer and use the rectified current to supply the output phase of the vertical deflection. This vertical phase itself then loads the horizontal winding so that the horizontal sweep current is modulated with the frequency of the vertical deflection. Although this arrangement is satisfactory, it would still be desirable to provide a raster correction circuit that provides greater control over modulation.

According to the present invention, there is provided an east-west pillow distortion correction circuit for a television deflection circuit, comprising a vertical deflection generator and a horizontal deflection generator supplying and includes a controllable semiconductor element having a control signal applied to the control electrode from the vertical deflection circuit to vertically change the resistance of the main current path of the semiconductor element during each portion of the vertical deflection period when the main current path is biased in the discharge direction to correct pad distortions. This correction circuit is characterized in that the main current path of the semiconductor element is biased in the discharge and blocking directions during each horizontal deflection period, by a horizontal signal supplied by the switching circuit, and that the control circuit connected element impedance.

A more detailed description of the present invention will be given in the following description with reference to the accompanying drawing, which shows a correction circuit according to an embodiment of the present invention.

3 6291 8 In this figure, which shows a horizontal deflection system including a pad distortion correction circuit, a winding 10a is connected between the input reactance 10 of a voltage supply B + and a switch terminal 11 in a bidirectional current. The winding loa is also connected to the commutating winding 13 and to the capacitor 15 and to the second switching terminal from the second bidirectional current conducting switch 16. The auxiliary capacitor 14 is connected between the commutating winding 13 and the capacitor 15 and ground. The switch 16 is also connected to the ground through the horizontal deflection windings 18 and the S-forming capacitor 19, and through the primary winding 20a of the horizontal output transformer 20 and the latch capacitor 21 to the ground. The horizontal oscillator 12 is connected to one of the parts on the base electrode, i.e. the gate in the switch 11. The winding 10b from the inlet reactor 10 is connected via a waveform shaping circuit 17 to provide switching signals to one of the parts in the switch 16. The circuit described heretofore is a horizontal deflection circuit. in U.S. Pat. No. 3,452,244. Since a description of the operation of this circuit is unnecessary to understand the present invention, it is sufficient to say that the horizontal deflection circuit includes a sweeping current through the horizontal deflection winding 18 and induces horizontal frequency energy in the primary winding 20a at the horizontal output transformer 20. This horizontal energy forms a relatively short time.

The winding 20b from the horizontal output transformer 20 supplies horizontal return pulses to a conventional high voltage rectifier and multiplier 22 so as to provide a positive high voltage of the order of 25,000 volts to supply the last switch terminal from the television picture tube.

The remainder of the circuit in this figure includes a circuit in accordance with the present invention to provide cushion distortion correction for the horizontal sweep current. The winding 20c of the transformer 20 is connected to the ground via a series-connected capacitor 23 and a resistor 24, a diode 25 arranged in a manner similar to that shown, and a capacitor 26 via a parallel connection and an adjustable inductance 27. The same switching terminal from the winding 20c is also connected to the emitter via a path limiting resistor 30 from the collector of a diode 28 of polarity and a transistor 29 to the emitter as indicated. A bias circuit consisting of a resistor 31 and a potentiometer 32 is connected between the collector and the base electrode by a transistor 29.

The second switching terminal of the winding 20c is connected from the series-connected collector to the emitter via paths in transistors 43 and 44. Transistors 43 and 44 form the output stage from the vertical offset amplifier. The complementarily symmetrical output stage is powered by a conventional vertical deflection generator and actuator 45. This vertical frequency deflection current is connected through a DC blocking capacitor 46 to the vertical deflection coils 47 and 48 and through a current-testing feedback resistor 49 to ground.

The top terminal of the winding 20c is also connected to the second terminal of the storage capacitor 42, of which the second terminal is connected to the ground via a parallel connection of a diode 39, a capacitor 40 and a resistor 41. This switch terminal of the capacitor 42 is also connected to the ground through the parallel connection of the resistor 38 and the capacitor 37 and the adjustable resistor 36. The side output of the adjustable resistor 36 is connected via a resistor 33 to the base electrode of the transistor 29. A phase shifting circuit consisting of a series-connected capacitor 34 and a potentiometer 35 is connected between the base electrode of the transistor 29 and the connection point of the feedback resistor 49 and the vertical deflection winding 48.

In operation, diode 25, inductance 27, capacitor 42, and diode 39 act as rectifying and storing devices for horizontal frequency energy winding 20c. The horizontal frequency energy is illustrated by waveform 54. The polarity of diode 25 rectifies a portion of the drawing from waveform 54. The rectified current is stored by charging to capacitor 42. Diode 39 prevents a positive charge from accumulating at the bottom switch terminal of capacitor 42. Capacitor 26 acts as a radio frequency bypass capacitor for rectifier 25. Capacitor 23 and resistor 24 act as damping components to prevent oscillation of this circuit. Diode 28 operates to block 5 6291 8 of any positive voltage from the collector of PNP transistor 29. The capacitor 34 and the resistor 35 form a phase transfer circuit for differentiating the waveform 51 that develops over the test resistor 49 for purposes to be described later. It should be noted that the waveform 53 at the vertical deflection frequency develops at the junction of the capacitor 42 and the diode 39.

This waveform is indicative of the conduction of the vertical output transistor 43 during the latter half portion of each vertical drawing time slot. The circuit consisting of the capacitor 37, the resistor 38, the capacitor 40 and the resistor 41 forms an integrating circuit for forming a parabola 5Q from the waveform 53.

This parabola is connected via a resistor 33 to the base of the transistor 29. The adjustment of the adjustable resistor 36 determines the magnitude of the parabola 50 fed to the base of the transistor 29.

Transistor 29 and associated control circuitry acts as an adjustable impedance to bypass rectifier 25 and inductance 29 by bypassing a certain amount of rectifier current so that the current in rectifier 25 is changed parabolically at the vertical deflection frequency. Parabola 50 coupled to the base of transistor 29 allows it to conduct more strongly at the beginning and end of the time slot, as indicated by the most negative parts in waveform 50. During the portions of the vertical slot where transistor 29 conducts the most, the lowest impedance is generated for horizontal frequency current when inductance 27 is relatively high. energy, is bypassed. This causes a faster charging current to flow to the charging capacitance 42. This faster charging current prevails at the top and bottom of the raster and results in a horizontal sweep current envelope illustrated by waveform 52. This envelope of modulation the amplitude is smaller for those portions that represent the top and bottom of the scanned raster relative to its center. Thus, the side line cushion distortion is corrected by parabolically changing the horizontal sweep current at the vertical deflection frequency. Inductance 27 also regulates the vertical supply voltage.

The function of the phase shift circuit consisting of the resistor 35 6291 8 6 and the capacitor 34 is to differentiate the negatively moving portions of the vertical sawtooth waveform 51 so that they are added to the parabola 5 to make an adjusted adjustment to the amount of correction at the top of the grid. The adjustment of potentiometer 35 implements the operation of this top and variable correction.

It can be seen that when transistor 29 and associated circuitry cannot be implemented with a relatively small amount of parabolic vertical frequency correction for horizontal energy by charging and discharging charge capacitance 42. However, increasing the bypass transistor 29 and associated circuitry effectively bypasses relatively high impedance 27 vertical frequency modulation for horizontal power supply. In addition, increasing the bypass path associated with transistor 29 affects the amount of actual rectifying current that is regulated parabolically. The load of the winding 20c at the vertical deflection frequency is reflected to the winding 20a and causes the commutation current to be directed more to the transformer 20 instead of passing through the deflection windings 18 to the S-shaping and storage capacitor 19 during each horizontal deflection cycle commutation portion.

Although one particular arrangement has now been described above, it should be understood that numerous modifications to the embodiment described above can be readily made. For example, return rectification instead of drawing rectification could be accomplished by reversing the winding 20c. Besides, any suitable deflection circuit other than the type of SCR used that has been described could also be used. Besides, the vertical deflection circuit need not be of the complementarily symmetrical type but may also be of any other suitable type.

It should be noted that, as an alternative embodiment, the cathode of diode 28 may be connected to the anode of diode 25 instead of the cathode of diode 25, and accordingly the bypass inductance and thus current control passes through the rectifying diode 25.

The following tabulates the values of the circuit components in the raster correction circuit shown in the figure below: 7 6291 8 C23 to 0.0022 f R2 4 to 220 ohms C26 to 560 pf. R30 - 1 ohm C34 - 1.5 .mu.m. R31 - 1,5 Rohm C37 - 350 uf. R32-1 Rohm C40-100 yuf. R33 - 120 ohms C42 - 1000 / uf. R35 - 1 Rohm R36 - 100 ohms R38 - 27 ohms R41 - 2.4 ohms L27-250-300, ιιΗ Q29-2N6111.

Claims (4)

8 6291 8 An east-west pillow distortion correction circuit for a telecommunication receiver deflection circuit, comprising a vertical deflection generator and a horizontal deflection generator supplying a horizontal frequency deflection current to a horizontal deflection coil with a half-deflection coil (28, 29), to the control electrode of which a control signal is applied from the vertical deflection circuit to vertically change the resistance of the semiconductor element main current path during each part of the vertical deflection period when the main current path is biased in the discharge direction to correct pad distortion, characterized in biased in the discharge and blocking directions during each horizontal deflection period, by a horizontal frequency signal supplied by the switching circuit (20), and that a control silicon connected to the control electrode of the semiconductor element (28, 29) ri (31-42) generates a parabolic control signal from signals derived from the vertical deflection circuit (43-45) to increase the horizontal current load at the beginning and end of the vertical line period by modulating the impedance of the semiconductor element (28, 29). Correction circuit according to Claim 1, characterized in that the second impedance (23-27) is connected in parallel with the semiconductor element (28, 29) to be controlled. A correction circuit according to claim 1, characterized in that the switching circuit (20) biases the impedance-generating controllable semiconductor element (28, 29) in the discharge direction during the return cycles of the horizontal deflection circuit and in the blocking direction during the line cycles, and that the vertical frequency signals change the semiconductor element A correction circuit according to claim 1, characterized in that the switching circuit (20) biases the impedance-generating controllable semiconductor element in the discharge direction during the line cycles of the horizontal deflection circuit and in the blocking direction during the return cycles, and in vertical signals controlling the semiconductor element conduction state during line cycles. 6291 8 9