KR800000957B1 - Pincushion correction circuit - Google Patents

Abstract

A cct. suitable for use in a TV receiver is composed of a 1st capacitor(22). a vertical deflection winding(23) coupled in parallel with the capacitor, means(14, 18, 19, 20, 21) coupled to the 1st capacitor for charging the capacitor with resp. decreasing and increasing amounts of horizontal rate energy during resp. 1st and 2nd scan portions of each vertical deflection interval and a resonant cct(24-27). tuned to th horizontal rate coupled to the means, for receiving the decreasing and increasing amounts of horizontal rate energy.

Description

Pin cushion correction circuit

1 is an improved schematic diagram of a television receiver using a pin cushion correction circuit according to the present invention.

2a to 2g are curve diagrams showing the various current and voltage waveforms obtained in FIG.

The present invention relates to a pin cushion distortion correction circuit suitable for use in a television receiver.

It is known in the art that the upper and lower pin cushion distortion of the raster on the television tube can be eliminated by modulating the vertical ratio scan current through parabolic amperometric deflection coils at the horizontal scan ratio.

In general, the preferred modulation is active circuits in which the transistor stage amplifies the horizontal specific energy and has an output electrode coupled to the vertical scanning circuit, or the control winding or primary winding of the reactor or transformer is activated by the horizontal specific energy and the secondary winding is It is done by a passive circuit placed in the circuit with a vertical deflection winding. In addition, there should be a device in which the polarity of the horizontal ratio modulation is reversed at the center of the vertical scanning period and the modulation is maximized at the beginning and end of the vertical period and minimum in the middle. Usually these circuit elements and their required interconnects are relatively complex and expensive to the device.

The pin cushion correction circuit includes a first capacitor coupled in parallel with the vertical deflection winding. The device coupled to the first capacitor charges this capacitor as it reduces and increases the amount of horizontal ratio energy, respectively, during the first and second scan portions of each vertical deflection period to provide a linear vertical ratio sawtooth current in the winding. . An almost horizontally tuned resonant circuit is coupled to the device to receive a decrease and increase in the horizontal ratio energy and a portion of the resonant circuit is generally parabolic horizontal vision in the winding of this phase to reduce top and bottom pincushion distortion. It is combined with a vertical winding to provide a flow component.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

In FIG. 1, the remainder of the figure, except for the pincushion correction circuit, which will be described next, is filed on July 14, 1975 by Peter E. Harper, entitled “Switched Vertical Deflection System,” US Patent Application No. 595,809 It shows a switched vertical deflection system similar to that described in the call. The horizontal ratio synchronous pulse 10 generates a sawtooth wave scanning current in a horizontal deflection coil 13 disposed around the kinesco off 17 and generates a horizontal ratio energy including horizontal output and retrace pulses in the primary winding 14a of the high-voltage transformer 14. It is coupled to input terminal 11 of generator 12. The tertiary winding 14b is coupled to the high-pressure back-up and rectifier device 15 to generate a relatively high direct current, which is coupled to the high-voltage terminal 16 of kinesco off 17.

Windings 14d and 14e are coupled in series to a circuit with SCR18, inductor 19, inductor 20 and SCR21, with the anode of SCR18 and the cathode of SCR21 grounded. The junction of inductors 19 and 20 is coupled to capacitor 22 and then in parallel to vertical deflection windings 23a and 23b and inductor 24. The lower part of winding 23b is coupled to ground via feedback resistor 41.

The feedback signal generated across the resistor 41 is coupled to a vertical generator 32 having a vertical synchronizing pulse 30 coupled to an input terminal 31. The vertical generator 32 is configured as an oscillator and a sawtooth generator to generate a suitable type of vertical ratio voltage sawtooth waveform coupled to the modulator 33. Winding 14c of transformer 14 provides modulator 33 with horizontal ratio winding pulses whose pulse width is modulated at the vertical ratio to generate horizontal ratio pulses, the pulses of which are each adapted to conduct SCR 18 and 21 in appropriate time order. Coupled to the gate electrodes. As pointed out in the above patent application, the gate pulses coupled to SCR18 cause an increase in delay with respect to the leading end of the horizontal retrace pulses during the first portion of each vertical period and the pulses coupled to SCR 21 have respective vertical deflections. A delay reduction occurs in relation to the leading end of the horizontal retrace pulses during the second portion of the period.

Referring to FIGS. 2A, 2B, and 2C, which show waveforms indicated by the same numerals in FIG. 1 in more detail, it is easier to understand the operation of the switched vertical circuit. At the beginning of each vertical sweep line period following T ₁ , SCR 18 is gated on and conducts a current 35 that charges capacitor 22 through a series resonant circuit comprising inductor 19 and capacitor 22. Winding 14d acts as a voltage source providing a horizontal retrace pulse 40 of approximately 80 volts amplitude and is polarized as shown in FIG. 1 such that current 35 flows through SCR 18 and the resonant circuit. This flow of current typically generates a sawtooth voltage wave 34 across the capacitor 22 during the vertical sweep line. During the first part of the vertical sweep line period T ₁ -T ₂ , SCR 18 is gated so that the amount of decrease in horizontal ratio energy accumulates in capacitor 22 as time increases. During the _second half of each vertical deflection period T ₂ -T ₃ , SCR 21 is gated on to increase the time of each horizontal retrace period, and the opposite polarity of increasing amplitude as explained by waveform 35 of FIG. 2C. Current flows into the capacitor 22.

During the crossover portion of T ₂ , SCR 18 and 21 conduct, so that the difference between their currents charges capacitor 22 and the remaining current is the quiescent current including SCR 18, winding 14d, inductor 19, inductor 20, winding 14e and SCR21. Note that it flows into the passage. Inductor 20 and capacitor 22 form a resonant charging circuit for capacitor 22 from pulses 40 generated across winding 14e during the period when SCR21 conducts.

The discharge path to capacitor 22 is grounded through vertical deflection coils 23a and 23b, inductor 24 and feedback resistor 41. Vertical deflection windings 23a and 23b provide a relatively high impedance for horizontal ratio energy, resulting in voltage waveform 34 in FIG. To be integrated.

It should be noted that the integration of voltage waveform 34 by deflection windings 23a and 23b causes the vertical ratio deflection current 36 in FIG. 2d to generally include a parabolic component at the horizontal deflection ratio. Therefore, the vertical circuit being switched inherently corrects the upper and lower pincushion distortions somewhat. However, depending on factors such as the vertical deflection winding impedance and the amplitude of the vertical scan current, the parabolic component of the vertical scan current does not have an appropriate phase or amplitude to satisfy the upper and lower pincushion corrections. Observing the voltage waveform 34 in FIG. 2B, it can be seen that the voltage is not an ideal sawtooth waveform, and the rising edge of the waveform is not straight but curved. Integrating waveform 34 by windings 23a and 23b results in a delayed parabolic current to avoid complete pincushion correction for the 110 degree deflection angle tube.

The pincushion correction circuit includes capacitors 25 and 27 connected in series with a parallel resonant circuit consisting of an inductor 24 and a capacitor 26. Capacitor 25 is coupled to capacitor 22 to receive drive current therefrom and the bottom of capacitor 27 is grounded. Resistor 28 and potentiometer 29 couple in parallel with inductor 24 and capacitor 26 and act to reduce oscillation to provide amplitude control for pincushion corrected current.

The drive current for the pincushion circuit is shown by current waveform 37 flowing through the capacitor 25 and the pincushion circuit portion to ground. The bowtie type horizontal specific current modulated at the vertical ratio has the same phase as the current waveform 35, which is the charging current for the capacitor 22 in the switched vertical circuit. In the expanded portion of current waveform 37 shown in FIG. 2E, the sharply rising portion after T ₁ is due to the rapid increase in the charge current 35 of capacitor 22. The next flat portion of current waveform 37 represents the time to decrease the current waveform portion in waveform 35 and increase the voltage portion of voltage waveform 34. During this period, the SCR 18 conducts while providing low impedance to the pincushion correction circuit. At the end of this portion of waveform 37, the current changes to sinusoidal because capacitor 22 is in series with the pincushion circuit, which includes capacitor 25, inductor 24, capacitor 26, and capacitor 27, which currently constitute a series resonant circuit. This series circuit exists during the time when SCR18 and SCR21 are not conducting.

The drive current of waveform 37 generates the resonant current shown by waveform 38 of the second f in a parallel resonant circuit comprising an inductor 27 and a capacitor 26. The resonant frequency of this circuit is determined by inductor 24 and capacitor 26 connected in parallel with capacitors 25 and 27 connected to ground via capacitor 22. In determining the resonant frequency, the inductance and capacitor 22 of the vertical windings 23a and 23b can be ignored because their values are relatively large compared to the rest of the pincushion circuit reactive elements. The current shown by waveform 38 is related to the current through windings 23a and 23b as shown by current waveform 36 of FIG. 2d because the interconnection of vertical windings 23a and 23b and inductor 24 is involved as shown in FIG. It is 180 degrees out of phase.

The ringing voltage across the parallel resonant circuit is shown by voltage waveform 39 in FIG. Voltage waveform 39 represents a pincushion correction current source that allows the correction current shown by waveform 41 in FIG. 2G to flow from the center terminal of deflection windings 23a and 23b to external terminals. This correction current waveform 41 delays the ringing voltage waveform 59 by approximately 90 ° because the inductance of the deflection windings 23a and 23b is relatively high. The phase of the calibration current waveform 41 is determined by setting a phase control inductor 24 that can be installed to advance the phase of the driving voltage waveform 39 of FIG. 2g to compensate for the delayed phase parabolic current waveform described above, and the waveform of the waveform of FIG. It is intended to be added to the parabolic current component shown at 36. This increases the parabolic component at about half the horizontal ratio between the continuous horizontal retrace pulses of FIG. 2A, which is a phase suitable for performing pincushion distortion correction.

Adjusting the inductor 24 resonates the pincushion circuit above or below the horizontal ratio frequency that changes the phase of the calibration current so that it can be properly adjusted to achieve the desired pincushion correction as a desired combination of peak vertical deflection current and deflection winding parameters. Frequency changes The resonant circuits 24 and 26 may be coupled to the vertical deflection winding 23 by means other than a direct coupling, for example by a transformer.

The preferred pincushion correction circuit is relatively economical and efficient because it uses fewer components and directly uses the vertically modulated horizontal non-corrugated waveform generated by the switched vertical deflection circuit.

The following is a list of circuit components that provide pincushion correction for 110 ° large screen water tubes, such as RCA Co-Porcesion Model No. A67-610X.

Claims (1)

As described in the text and shown in the drawings, the first capacitor 22, the vertical deflection winding 23 coupled in parallel with the capacitor 22, and the linear vertical ratio sawtooth currents in the winding 23, respectively. Charging devices 14, 18, 19, and 20 coupled to the first capacitor 22 to charge the capacitor 22 with a gradual decrease and increase in horizontal ratio energy during the first and second scan portions of the vertical deflection period. In the pincushion correction circuit comprising: 21, in particular, a tuned resonant circuit 24 of the horizontal ratio logger coupled to the charging device 24, 25, 26, 27 to receive a reduction and increase in the horizontal ratio energy. Parabolic horizontal ratio in the winding of this phase, coupled to a portion 24, 26 of the resonant circuit 24, 25, 26, 27 and reducing top and bottom pincushion distortion A coupling device coupled to the vertical windings 23 to provide a current component. Pincushion correction circuit.

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