FR2541543A1 - TV receiver image size adjustment circuit - Google Patents

Abstract

The circuit provides an image size setting signal (29) which is fed to a modulator (25) for adjustment of the horizontal flyback voltage to obtain the required adjustment of the image size in the horizontal direction. A control signal (C3) is supplied in dependence on the image size adjustment in the horizontal direction and is fed to the vertical deflection circuit (L8) providing the vertical deflection current for the vertical deflection coil (LV). The current amplitude is adjusted via the control signal to obtain the required adjustment of the image size in the vertical direction. Pref. a setting control is provided for adjustment of the raster width independent of the horizontal image size setting signal (29), or the vertical image size control signal (C3).

Description

 The present invention relates to a circuit for adjusting the size of the image which allows the simultaneous variation of the height and the width of a scanned frame. The relationship between height and width is kept proportional to maintain a constant aspect ratio of the image. The circuit can be controlled either locally or by remote control; the viewer receives the impression of a zoom effect. The operating range can be chosen between underscan and overscan.

The high voltage or other similar parameters of the television set are not influenced by the variation in the size of the image.

 According to one aspect of the invention, the image size adjustment circuit is incorporated in a modulator circuit which is used to produce a side pad correction for horizontal deflection. A horizontal dimension adjustment signal is applied to the modulator circuit to vary the horizontal go voltage to change the dimension of the image in the horizontal direction. A vertical deflection circuit produces, in a winding, vertical deflection. a vertical scanning dye whose amplitude varies with the variatiodu Uu vertical dimension adjustment signal to change the dimension of the image in the vertical direction.

 According to another aspect of the invention, the signal for adjusting the vertical dimension is produced from a voltage developed in the horizontal deflection circuit which varies current with variations in the voltage to go horizontal. . Thus, changes in the vertical dimension follow changes in the horizontal dimension to maintain an image having a constant aspect ratio.

The intention will be better understood, and other aims, characteristics, details and advantages thereof will appear more clearly during the explanatory description which follows, made with reference to the appended schematic drawings-given solely by way of example illustrating several embodiments of the invention and in which
- - Figure 1 illustrates a circuit for adjusting the dimension of the image of a television set according to the invention;
FIG. 2 shows a specific embodiment of the east-west frame correction adjustment circuit of FIG. 1, which includes a capacity for adjusting the dimension of the image;
- Figure 3 shows waveforms useful for explaining the operation of the circuit of Figure 1 ;;
- Figure 4 shows another embodiment of a circuit for adjusting the size of the image according to the invention; and
- Figure 5 illustrates a specific embodiment of the east-west frame correction adjustment circuit of Figure 4, including a possibility of adjusting the size of the image.

The image size adjustment circuit according to the invention is illustrated in FIG. 1 as being incorporated in a current supply and deflection circuit which produces a correction in lateral or east-west cushion. Such a current supply and deflection circuit is described in British patent application No. 2,094,085A, published on September 8, 1982 entitled
REGULATED DEFLECTION CIRCUIT, by PE Haferl and in British Patent Application No. 2,119,209A, published November 9, 1983, entitled VARIABLE HORIZONTAL DEFLECTION
CIRCUIT CAPABLE OF PROVIDING EAST-WEST PINCUSHION CORREC
TION, by PE Haferl.

In FIG. 1, a current supply source in synchronous switched mode on line 21 for the television set applies energy or current, by a supply inductor, a horizontal return transformer
T1, to the horizontal deflection circuit 22 which is coupled to the winding w1 of the return transformer. A horizontal deflection return pulse voltage VO, illustrated in FIG. 3b, is developed by the horizontal deflection circuit 22 at the collector of the horizontal output transistor Q1 controlled at the horizontal deflection frequency by a horizontal oscillating and driving circuit 19 The deflection return pulse voltage is developed by a resonant horizontal deflection return circuit comprising a horizontal deflection winding LH and horizontal deflection return capacitors CRD1 and CRD2.

During the horizontal return, the inductance of the winding w1 of the transformer T1 and a return capacitor C RT form a second resonant circuit tuned almost on the return frequency of horizontal deviation
A pulse voltage V1, illustrated in FIG. 3a, is developed in the winding 1. In FIG. 3a t1 designates the return time and t2 designates the time to go.

 The return pulse voltage of the return transformer V1 is coupled, by the transformer to the other windings w2nz4, of the return transformer.

The voltage in the high-voltage winding W4 energizes a high-voltage circuit 18 to produce a final voltage at a terminal U. The voltage in the winding w3 excites various other charging circuits of the television illustrated, as a whole, in FIG. 1 , by element 23. The primary winding Wp of the return transformer T1 is provided with a socket and the signal at the socket is reapplied along a line 24 to the current supply source in switched mode 21 to synchronize the operation of the power source with the horizontal deflection and to regulate the return pulse voltage of the return transformer V1 and maintain its amplitude constant.

 A side cushion correction modulator circuit 25 is coupled to the horizontal deflection circuit 22 to produce a side cushion correction of the horizontal scanning current flowing in the horizontal deflection winding LH. The modulator circuit 25 stores the energy obtained by the winding w 2 of the return transformer during the horizontal outward interval.

This energy is transferred to the horizontal deflection circuit 22 during the horizontal return interval by the secondary winding of the transformer T2 and the diode D3. A return pulse voltage V2; illustrated in Figure 3c, is developed in a diode D2, which diode is part of an arrangement of horizontal damping diodes comprising diodes D1 and D2. The deflection return pulse voltage VO is equal to the algebraic sum of voltage V2 and the pulse voltage of return transformer V1.

The modulator circuit 25 varies the amplitude of the voltage V2 at a vertical frequency, in a parabolic manner, to modulate the pulse deflection voltage Vg at a vertical frequency in a parabolic manner. This results in the modulator circuit 25 concurrently varying the horizontal forward voltage which is applied to the horizontal deflection winding.
LH by the capacitor Cs for shaping S during the switching operation of the horizontal output transistor Q1 and of the damping diodes D1 and D2.

The return pulse voltage of the return transformer F1 remains unmodulated in amplitude due to the regulation produced by the current supply source in switched mode 21. The high voltage and the other voltages of the transformer are not affected by the modulation. east-west or by adjustments of the width of the frame which are accomplished by an adjustment circuit 26 of the modulator 25. Similarly, as the secondary winding of the transformer T2 is interposed between the resonant horizontal deflection and return circuits of the return transformer, the winding is used to isolate the two resonant circuits during the return to the deflection return frequencies and higher frequencies. Thus, the modulation of the load current of the waveform of the pulse voltage
V1 leaves the waveform of the voltage VO relatively unaffected.

 The voltage V3 measured from the pointless terminal of the winding w1 of the return-to-ground transformer includes the algebraic sum of the voltages V1 and VO as shown in Figure 3d. Consequently, the voltage V3 is also modulated by the modulator circuit 25 and it varies with the variations in the horizontal scanning current. The voltage V increases with the increase in the amplitude of the horizontal scanning current or the width of the frame.

According to one aspect of the invention, the voltage V3 is used to produce the vertical sawtooth voltage, the waveform 27 of FIG. 1, used by the vertical deflection amplifier 28 to produce the vertical scanning current in the vertical deflection winding
Resistors R2 and R3 divide the voltage V3; a capacitor C2 filters, the voltage divided the components at the horizontal frequency and the variation at the vertical frequency introduced by the modulator 25.

A voltage V4 is produced at a terminal 33 which is proportional to the DC value of the voltage V3 The DC value of the voltage V3 is adjusted by the potentiometer R21 for adjusting the width of the adjustment circuit 26and it is more regulated by a dimension adjustment voltage applied to the adjustment circuit 26 to a terminal 29. The dimension adjustment voltage can be developed locally by manual adjustment of a potentiometer or else it can be produced remotely by a circuit conventional infrared or ultrasonic remote control, similar to the
sound remote control.

The dimension adjustment signal at terminal 29
directly determines the amplitude of the sweep current
horizontal by directly adjusting the amplitude of the
deflection return voltage VO by
operation of the modulator circuit 25. However,
indirectly, as the voltages V3 and V4 are pro
portable at voltage S0, the dimension adjustment signal at terminal 29, in addition to serving as
horizontal dimension adjustment signal, also used
allowing the voltage V4 to function as a vertical dimension adjustment signal for the vertical scanning current in the vertical deflection winding
A circuit forming a vertical ramp comprising a resistor R4 and capacitors c3 and C4 is coupled to the vertical deflection amplifier 28. The capacitors
C3 and C4 are loaded by terminal 33 to produce a sawtooth waveform 27, during the vertical go interval, the amplitude of which is proportional to the voltage V. To initiate the vertical return interval ,
the vertical deflection amplifier 28 discharges the capacitors C3 and C4 in a conventional manner.

In addition to the dimension adjustment circuit
the image according to the invention, the potentiometer R21 for adjusting the width, for the horizontal deflection circuit22, and a potentiometer 35 for adjusting the height for the vertical deflection amplifier 28,
act independently of the dimension adjustment signals which are developed. The potentiometer 35, at
as an example, can adjust the height of the image by
adjusting the amount of AC feedback of the sawtooth voltage developed by the sampling resistor R in Figure 1.

s
While adjusting the width and height,
the image size adjustment signal developed at terminal 29 is established at a certain level names au. The width and the height are then adjusted to the condition of normal size of the image. When the width and height adjustments have been made, the level of the dimension adjustment signal can be changed regardless of the width and height adjustment to the level required to produce the desired larger or smaller dimension of the 'picture.

 The range of variation of the image dimension is limited, at the lower end, the smallest dimension, by the value of the voltage V1, which voltage imposes a lower limit on the amplitude of the horizontal deflection current. The range is limited at the upper end by the amplitude of the voltage developed in the winding w2 of the return transformer and by the ratio of the turns of the transformer T2. These two factors determine the maximum energy that can be supplied to the horizontal deflection winding LH during each horizontal return interval. Another limit to the maximum image size comes from the maximum voltage that the horizontal output transistor Q1 can resist.

 As the voltage Vd is proportional to the size of the image, the voltage can be applied as conventional circuits of contrast, brightness and color saturation which are not shown in FIG. 1 to adjust the contrast, the saturation of the colors and brightness with variations in the size of the image.

 FIG. 2 shows a part of the circuit of FIG. 1 comprising a specific embodiment of the modulator circuit 25 for lateral or east-west cushion correction, having a capacity for adjusting the dimension of the image according to the invention. Items similarly identified in the two figures function similarly or represent similar amounts.

To produce an east-west bearing correction, the pulse width of the transistor Q2 of the modulator circuit 25 of FIG. 1 is modulated at a vertical frequency in a parabolic manner by the adjustment circuit 26 of FIG. 2. The voltage in teeth vertical saw 41 developed by the vertical deflection winding Lv is integrated to obtain a vertical parabolic signal 42 in the capacitor C5. The dish is inverted and amplified by a transistor Q30 A vertical sawtooth voltage is applied to the emitter of the transistor
Q3 by the trapezoid adjustment resistor R7 to avoid the development of a slight tilting of the parabolic signal 43.The amplitude of the symmetrical and inverted parabolic signal 43 is adjusted by a resistor Rg and it is applied by the current blocking capacitor DC C6 to the reverse input terminal of a comparator U2.

A C8 capacitor is charged by a current source
Q4 and it is discharged at each horizontal return interval by a comparator U1 to which the pulses 31 of horizontal deflection return are applied. A horizontal ramp signal 30 is thus developed. The signal 30 is applied to the direct input terminal of the comparator U2 and it is compared with the vertical parabola to the reverse input terminal to produce, during each horizontal deflection cycle, a niche switching signal VEW, at the comparator output.

The positive edge of VEW occurs during the horizontal go interval at a variable and adjustable time to produce a modulation of the pulse width of
VEW at a vertical frequency in a parabolic manner.

The switching signal is applied to the base of the switching transistor Q2- to produce an east-west pad correction.

 The size of the image is adjusted by the variable current source Q4, through which a variable DC voltage can be added. to the horizontal ramp signal 30 of FIG. 2. The waveform in solid line of signal 30 is obtained with a signal for adjusting the dimension of the image at a low level applied to terminal 29, resulting in a dilated image. The dotted waveform of ramp 30 is obtained with a high level adjustment signal and results in a contracted image.

 A feedback circuit has been incorporated into the east-west cushion correction modulator adjustment circuit 26 to improve the geometry and stability of the image. The deflection return pulse voltage developed in the resistor R17 is illustrated in FIG. 2 by the waveform 31 on a scale associated with the horizontal frequency and by the waveform 32 on a scale associated with the vertical frequency. The deflection return impulse voltage contains the east-west modulation as indicated by the envelope of the waveform 32. The deflection return impulse voltage is reproduced at the reference of the mass by the capacitor Cg and the diode D5 and it is added by the resistors R21, R22 for adjusting the width, to the ramp voltage. horizontal developed by the integration capacitor C8.

 If the vertical dish and / or the DC component added by the feedback circuit to the positive input of the amplifier U2 is not equal to the drive signal at the negative input, then the time delay of the switching signal at the output of amplifier U2 changes and the error decreases.

 By this feedback mechanism, variations in the beam current or the audio load on the return transformer T1 of FIG. 1 do not influence the east-west correction, the width or the size of the image as we will explain it better now. Assuming that Q2 is continuously off1 the image is very small and the east-west correction is zero.

In this condition, the horizontal deflection winding
LH is attacked by the return voltage of the return transformer which produces a driving current through the diode D2 and LH. This current flows mainly during the first half of the return and therefore does not strongly disturb the current in the deflection winding. However,
certain load modulations may be visible.

 When Q2 is in operation, the additional attack power for the east-west correction and the dimension is taken from the winding of the transformer w2 which contains all the load modulation disturbances. An open circuit operation of the modulator would reintroduce these disturbances into the horizontal deflection circuit 22.

Furthermore, open circuit operation would require a ramp at the horizontal frequency carefully configured in the modulator to obtain the linearity of the frame over the entire width or dimension range.

 Thus, the feedback serves to prevent the reintroduction of effects due to the load by the winding W2. Furthermore, the geometry is improved because the horizontal ramp of the modulator does not require any particular shaping.

Stability is improved because the DC component is incorporated into the feedback. This results in a regular adjustment of the width or dimension.

 The adjustment circuit 26 of FIG. 2 also has direct input of the information on the beam current to the positive input terminal of the amplifier U2 by the resistor R23. The beam current formation can be obtained from any practical point in the television for example, at the input of the conventional beam current limiter. As the beam current increases, for example, the final voltage decreases, which tends to cause an increase in the size of the image.

To directly compensate for this effect, the current information of the beams is added by the resistor R23, to the horizontal ramp signal of FIG. 2 in a way which results in the modulator circuit of east-west correction or of side cushion. reduces the amplitudes of the horizontal and vertical scanning currents resulting in a stable dimension of the image with variations in the beam current.

 Current consumption in the east-west cushion correction modulator circuit 25, where the adjustment of the image size according to the invention is incorporated, is proportional to the amplitudes of the horizontal and vertical scanning currents. Thus, no additional current is dissipated by this circuit at a normal dimension of the image in comparison with a modulator circuit where the adjustment of the dimension of the image is not incorporated.

 FIG. 4 shows another embodiment of a circuit for adjusting the size of the image according to the invention. Items identified as in Figure 1 operate in a similar fashion or represent similar quantities. In FIG. 4, the horizontal deflection circuit 22 is supplied by a regulated voltage source B + F the switched mode power source 121. In such a deflection circuit, the energy which circulates in the return transformer T1 is substantially lower than in the return transformer of the deflection circuit of figure 1. Usually, the low energy in circulation in the return transformer of figure 4 results in a bad impedance of final voltage source. This problem is solved by adding a capacitor C6 between the earth and the pointless terminal of the primary winding w1 of the return transformer T1.

 Capacitor C6 produces a high frequency current return to ground. The supply current at the final voltage, at frequencies including the harmonies of the deflection return frequency, flows during the horizontal deflection return interval between the horizontal deflection circuit22 and the return transformer T1 in passing by capacitor C6. This arrangement significantly improves the source impedance of the final voltage. The diode D5 is used to disconnect the horizontal deflection circuit 22 during the return, from the regulated B + voltage supply source when the voltage V3 increases beyond the voltage B +.

 Figure 5 shows a specific embodiment of the east-west frame correction adjustment circuit 26 of Figure 4. Items identified as in the adjustment circuit of Figure 2 operate in a similar fashion or represent similar amounts . In FIG. 5, the dimension adjustment voltage developed at terminal 29 is applied by an inverting transistor Q5 to the reverse input of the comparator U2. In addition, two size limiting potentiometers, R41 and R42, have been added. These potentiometers determine the size adjustment range.

The limiting potentiometers prevent the east-west modulator circuit from being saturated or cut due to an excessive adjustment of the dimension adjustment circuit.

Frame correction cannot be accomplished when the modulator is saturated or muted.

 A typical capacity of the image size adjustment range of the circuit of FIGS. 1 and 2 using an image tube at 1100, a 66 cm screen with an S4 winding is as follows: 30% overscan capacity; 208 sub-scanning capacity.

Claims (7)

 1. Circuit for adjusting the size of an image for a circuit for viewing a television frame, of the type comprising  a horizontal deflection winding;  a horizontal deflection circuit for periodically applying a horizontal forward voltage to said horizontal deflection winding to produce a horizontal sweep current therein,  a modulator circuit responding to the adjustment signals to vary said voltage to go horizonta) to develop concurrent variations in the amplitude of said current of balayaanhorizontal ;;  means for producing a side pad adjustment signal which is applied to said modulator circuit to vary said horizontal going voltage to a vertical frequency to develop variations in the amplitude of said horizontal scanning current which produces said pad correction;  a vertical deflection winding; characterized by  means (29) for producing a horizontal dimension adjustment signal which is applied to said modulator circuit (25) for varying said horizontal voltage to change the dimension of the image in the horizontal direction;  means (V4) for producing a second adjustment signal indicating changes in the size of the image in the horizontal direction; and  a vertical deflection circuit (28) responsive to said second adjustment signal to produce, in said vertical deflection winding (LV), a vertical scanning current whose amplitude varies with variations in the second adjustment signal to change the dimension of the image in vertical direction  2. Circuit according to claim 1 characterized by means (R21) for adjusting the width of the frame independently of the horizontal dimension adjustment signal (at 29) which is applied to said modulator circuit (26).  3. Circuit according to claim 1 characterized by means (35) for adjusting the height of the frame independently of the vertical dimension adjustment signal (in C3i which is produced.  4. Circuit according to claim 1 characterized in that the aforementioned means for producing a second adjustment signal comprises means (R2, C2-, R3) coupled to said horizontal deflection winding (LH) to produce a voltage which varies concurrently with the variations of the horizontal go voltage which are produced by the horizontal dimension adjustment signal.  5. Circuit according to claim 4 characterized by means (R23> for producing a modulator adjustment signal representative of the variations in the current of the beams nt o01r concurrently varying the amplitudes of the horizontal and vertical scanning currents in order to stabilize the width and the height of 1 image with variations in current of beams.  6. Circuit according to claim 4, characterized by means (R21, 35) for adjusting the width and height of the frame independently of the horizontal and vertical dimension adjustment signals which are produced.  7. Circuit according to claim 1 characterized in that the deflector circuit comprises a switching means (Q1) operating at a horizontal deflection frequency to periodically apply the voltage from horizontal to the horizontal deflection winding (LH) and a horizontal deflection return capacitance (CRD1î CRD2) for forming a resonant horizontal deflection return circuit with said horizontal deflection winding (LH), and comprising an inductor (T1) coupled to a power supply source (21) and a second capacitance (CRT) coupled to said inductor (T1) and said switching means (Q1) to form a second circuit resonating in said horizontal feedback interval to produce a pulse voltage which excites a load circuit (23) and where said modulator circuit (25) comprises an impedance (T2) interposed, in said horizontal return interval, in a current path between said deflection return circuit and said second resonant circuit, and a source of modulation current coupled to the impedance and responding to the side pad and horizontal dimension adjustment signals to produce modulation of the horizontal scanning current while the modulation current varies