HU200049B - Method and circuit arrangement for eliminating variation of picture size dependent on valume of 110 degree colour televisors - Google Patents

Abstract

The invention relates to a method for eliminating lautstaerkeabhaengiger Bildgroeszenaenderungen, especially of color television sets with 110 deflection Bildroehren, preferably for devices with great sound performance, the circuits of the device are operated by a switched-mode power supply voltages stabilized and the pincushion distortion of the 110-Bildroehre means of active East-West raster correction is set. The essence of the method is that the image width change occurring as a result of the change in the supply voltage of the horizontal deflection circuit 2 is compensated for by controlling the image width by means of a signal obtained from the supply voltage change of the horizontal deflection circuit 2 via an east-west correction circuit 4. The invention further relates to a circuit arrangement for carrying out the method, which has a stabilized switching power supply 1, a horizontal deflection circuit 2 and a Vertikalablenkschaltung 3, wherein the horizontal deflection circuit 2, an east-west correction circuit 4 is connected, which has a Verstaerker 41. The essence of the circuit is that between the supply voltage terminal 21, the horizontal deflection circuit 2 and the input 41 a of the amplifier 41 of the east-west correction circuit 4 - optionally via a diode 46 - a compensation network 5 is inserted. Fig. 1 {voice-dependent image magnification change; Color television devices; Switching power supply; stabilized supply voltage; horizontal deflection circuit; East-West correction circuit; vertical deflection; Amplifier; Compensation Network}

Description

BACKGROUND OF THE INVENTION The present invention relates to a method for eliminating volume-dependent image size changes of 110 ° color TV sets, in particular for use in high-power devices, wherein the circuitry of the device is operated from power supplies stabilized by a switching power supply. set it up.

The invention also relates to a circuit arrangement for carrying out the method of the invention, comprising a switching stabilized power supply source test diverting circuit and a vertical diverting circuit, an east-west raster correction circuit connected to the horizontal diverting circuit, and a east-west raster correction circuit.

With modern color TVs, dual-channel or stereo audio is increasingly a requirement, with a higher milk rate and HI-FI quality than the previous 2-3W. The sound power of these devices can reach up to 2 x 30 W. The demand for such devices is growing rapidly due to the presence of stereo video tape recorders and satellite reception, where the traditional two-channel broadcast is not yet broadcast.

The problem with increasing the power of the sound is the non-negligible internal resistance of the power supply of the device, which reacts to significant changes in the load of the sound power supply by interfering with other power supplies, i.e. causing a change in the sound speed. This results in a very disturbing phenomenon for the viewer, the image size varying with the speed of the sound, especially in the horizontal direction, since the deflection circuits are most sensitive to changes in the supply voltage.

In order to eliminate this interference, the stability of the power supply of the device and thus of the power supply voltage should be improved against the changing sound load. It would be desirable for the horizontal deflection circuit to e.g. The 150 V supply voltage should remain stable within 0.1 V while the sound level is eg. At 20 volts, you get a load ranging from zero to 2-3 Amps.

The horizontal deflector current load is also variable since there is a virtually 25 W load change depending on the brightness of the image tube. These numerical data illustrate what stringent stability requirements should be met by the power supply of a device with increased sound power. The problem is that the devices have to be disconnected from the network due to the connectors on the connector (SCART, headphones, speaker, etc.).

The most well-established and widespread technology in the state of the art for disconnection, efficiency, reliability and economy - so far, according to SIEMENS announcement - is the TDA 4600 SIEMENS integrated circuit power supply with integrated circuit. The power supply is provided by Funk-Technik 37 (1982).

Heft 1 Issue 21-25. pages discussing the benefits in detail. These benefits have been proven by the time elapsed and the widespread use of power supplies.

SIEMENS 'August 1987 issue of the .SCHALTNETZTEILE mit den Baustein dér Fanniié TDA 4600' summarizes the results of this type of power supply. The power supply on page 29 is recommended as a small crosstalk solution for color TVs. It can be seen from Figure 22 on page 31 that from 0.6 to 1 Amperes, a change in load of only 0.4 Amps already results in a 0.12 Volt change in the U1 supply voltage. From this it can be seen that this circuit is not able to achieve the required stability with a load change of 2-3 Amps.

The circuit layout shown on page 32 of the above publication has significantly improved stability parameters, which provides the required voltage stability by monitoring the secondary voltage and by separately re-regulating the primary side using additional active and passive components.

Because of the problems caused by the sound, attention is paid to this system, so-called. He turned to MASTER SLAVE circuits. This solution is also used by the ITT 3878 Hi-Fi H-type stereo, which uses an integrated circuit in both the primary and secondary circuits of the power supply, and re-regulates the primary circuit by installing a new life-transformer.

The disadvantage of the above solutions is that they are more expensive to service than the widespread Siemens switching, and they require an additional double insulated life protection component, such as an optocoupler or transformer, to re-regulate the disconnected secondary side to the primary side of the network.

The solution described in the German Patent No. 2,749,847 was also intended to eliminate the crosstalk caused by the change in volume. In essence, the coupling of the power supply transformer coil to the control coil is tight, while the coil supplying the horizontal deflection circuit is loosely coupled.

The disadvantage of this solution is that it requires a specially designed transformer, which is difficult to manufacture and crosstalk

EN 200049 The optimum damping effect also occurs at a given load and mains voltage. However, due to loose coupling of the horizontal deflection circuit power supply coil to the control coil, the supply voltage is no longer sufficiently stable, which can cause high voltage and image size stability problems.

Another simple core solution is provided by US Patent No. 3,026,064, which consists in inserting a resistor in the power supply between the power supply coil and the rectifier diode, reducing the crosstalk by about a quarter.

It is a disadvantage, however, that the degree of crosstalk attenuation in this solution is still unsatisfactory and still depends on the load, since the optimum effect of this solution can only be observed at a given radiation current and mains voltage.

Since in practice the color current of a color TV set always changes, the magnitude of the change can be as high as 20-25 watts - so far, the known procedures and switching arrangements have not been able to eliminate the crosstalk problem satisfactorily.

It is an object of the present invention to provide a method and circuit arrangement thereof which, while utilizing a well-established switching mode stabilized power supply, allows the variation in image size resulting from volume variation to be kept within the allowable range of the beam and roll.

The idea of the invention is based on the realization that instead of improving the crosstab stability of the power supply of TV sets, which is already within the technical limits, it is possible to decouple the horizontal picture size from the supply voltage of the horizontal diverting circuit by changing the -with the amplifier of the western raster correction circuit, a change in the image size of the opposite sign can be generated and thus the horizontal dimension change can be compensated by adjusting the magnitude of the power supply voltage applied to the amplifier input. This makes it possible to compensate for the horizontal change in size. This ensures that the horizontal image size remains stable despite multiple voltages in the horizontal deflection circuit.

According to an object of the present invention, the method of the present invention is used to eliminate volume-dependent image size changes of 110 ° color TV sets, in particular for use in high-power devices, wherein the circuits of the device are operated from power supplies stabilized by a switching power supply; is adjusted by a west-west raster correction, based on adjusting the horizontal dimension change due to power supply voltage change in the horizontal diverting circuit by controlling the horizontal dimension through the east-west raster correction circuit using a signal from the supply voltage change in the horizontal diverting circuit.

A switching arrangement according to the invention for eliminating volume-dependent image size changes of 110 ° color TV sets, in particular for use in high-power devices, comprises a switching mode stabilized power supply, a horizontal diverting circuit and a vertical diverting circuit and a horizontal diverting circuit. is connected, and the east-west raster correction circuit has an amplifier, - is configured with a compensating network between the power terminal of the horizontal diverting circuit and the input of the amplifier of the east-west raster correction circuit, optionally with a diode,

A further feature of the present invention may be that the compensation network consists of a passive compensation network comprising at least one music diode and resistor connected in series.

In a preferred embodiment, a NTC resistor capable of compensating for the temperature change is connected in series and / or parallel to the Zene diode.

In another embodiment, the compensation network consists of a current generator active compensation network with a current generator and a resistor connected in series with an input and ground, and a common point between the resistor and the current generator connected to an output of the current generator active compensation network.

In a further embodiment, the compensating network consists of an operational amplifier active compensating network having a resistor divider connected between its input and ground, and an operational amplifier, preferably variable variable amplifier, between the resistor divider, center point and the output of the operational amplifier active compensating network.

In either embodiment, the power terminal of the vertical diverting circuit, or at least the sliding circuit, is connected to a rectifier connected to the line transformer coil of the horizontal diverting circuit.

The main advantage of the method and circuit arrangement according to the invention is that, when applied, the volume-dependent change in the image size is minimized to a level not perceptible to the viewer.

It is also advantageous that it does not require any major interference in the circuitry of the device and can be implemented by installing some simple components.

HU 200049 A

The invention will now be described in more detail with reference to the drawings. The attached drawings show

Figure 1 is a general block diagram of a circuit arrangement according to the invention, a

Figure 2 is a possible embodiment of a circuit arrangement according to the invention for an East-West raster correction circuit constructed from discrete components;

Figure 3 is another embodiment of a circuit arrangement according to the invention for an East-West raster correction circuit with an integrated circuit,

FIG. 4 is a possible embodiment of an active compensation network, FIG

Figure 5 is a further embodiment of an active compensation network.

Figure 1 is a general block diagram of a circuit arrangement according to the invention. The power supply terminal 21 of the horizontal deflection circuit 2 is connected to the stabilized power supply source of the switching mode 1. The east-west raster correction circuit 4 is connected to the horizontal deflection circuit 2.

The east-west raster correction circuit 4 includes the amplifier 41. Between input 41a of amplifier 41 and power supply terminal 21 of the horizontal deflection circuit 2, a compensation network 5 is inserted.

The power terminal 31 of the vertical diverting circuit 3 is connected to the rectifier 23 of the horizontal diverting circuit 2 which is coupled to a series transformer coil 22. Instead of the vertical diverting circuit, it is sufficient to connect the sliding circuit 32 to the rectifier 23.

FIG. 2 illustrates an embodiment of a circuit arrangement according to the invention for an East-West raster correction circuit constructed from discrete elements. The east-west raster correction circuit is provided with an amplifier 41 whose input 41a is connected to the parabolic signal generating circuit via the size control potentiometer 4b and potentiometer 4a.

The passive compensation network 51 is connected to ground via a divider formed by the potentiometer 4a, the size control potentiometer 4b and the resistor 4c, and the input 41a of the amplifier 41 is connected to the center terminal of the size control potentiometer 4b.

Of the Zener diodes 51a, the first Zener diode connected to the potentiometer 4a is preferably 12 V, while the Zener diode outside the module is 110 V and the resistance 51b is 330 Ohm. Alternatively, the coupling capacitor 4d is 680 nF instead of 4.7 uF and the filter capacitor 4e is 100 nF instead of 22 uF. These changes do not substantially affect the transmission of the parabolic signal, but allow the compensation voltage at input 41a of the amplifier 41 to vary with the rate of change of sound.

Figure 3 illustrates another possible embodiment of a circuit arrangement according to the invention for an East-West raster correction circuit built with an integrated circuit. In this embodiment, the east-west raster correction circuit 4 comprises an integrated circuit 42 (TDA 4950 or TDA 8145) having an eight pin forming the amplifier input 41a. Since the integrated circuit 42 operates in switch mode, there is a need for line frequency pulses provided by the line transformer coil 24.

The pulse magnitude is determined by a network consisting of a resistor 45, a potentiometer 44 and a limiting Zener diode 43. The center terminal of the potentiometer 44 is connected to the amplifier input 41a via a rectifier member from diode 40 and capacitor 47.

The compensating network 5 consists of a passive compensating network 51, which is inserted between the power supply terminal 21 and the middle terminal of the potentiometer 44 and the common point of the diode 46. The passive compensation network 51 comprises a Zener diode 51a and a resistor 51b connected in series. The NTC resistor with the Zener diode 51a is connected in parallel.

Figure 4 illustrates another possible embodiment. The compensation network 5 is constituted by an active compensation network with a current generator 52 having a series-connected resistor 52a connected thereto and a current generator 52b and a resistor 52d. An impedance adapter 52c is inserted between the resistor 52a and the common point of the current generator 52b and the output of the active compensation network with the current generator 52c.

Figure 5 shows an example of a further possible embodiment. The compensation network 5 is formed by the operational amplifier active compensation network 53, which is provided with a resistor divider 53a coupled between its input and ground. The common point of the resistor divider 53a is connected to the input of a variable gain amplifier 53b. The output of the operational compensation active compensation network 53 is formed by the output of the operational amplifier 53b.

The circuit arrangement described above implements the method according to the invention as follows: The voltage supplied by the operating stabilized power source of the switch 1 varies with the rate of change of the volume in relation to the supply voltage 21 of the horizontal diverting circuit 2. Decreasing power will cause the image size to decrease.

The amplifier 41 of the east-west raster correction circuit 4 is designed to: a

HU 200049 A

A decrease in voltage at input 41a results in an increase in image size. If this effect is reversed, proper phase reversal should be provided.

His compensating network transmits the signal from the decreasing supply voltage at the power terminal 21 to the input 41a of the amplifier 41 of the east-west raster correction circuit 4, thereby increasing the image size. The compensating network 5 must be dimensioned such that the image size reduction effect of the voltage drop across the power supply terminal 21 is offset by the image size increase effect of the amplifier 41.

Measurements of the east-west raster correction circuit 4 constructed from the discrete elements of Fig. 2 showed that the horizontal reduction in voltage produced by the 1 V voltage change of the power terminal 21 can be compensated by a 0.5 V voltage reduction at the input 41a of the amplifier 41. It follows that the value of the resistances above the moving contact of the size control potentiometer 4b must be substantially the same as the resistances below the moving contact.

Tests of the East-West raster correction circuit 4 with the integrated circuits TDA 4950 or TDA 8145 shown in Figure 3 showed that the size reduction caused by the power drop at input 41a of amplifier 41, i.e., at the eighth leg of integrated circuit 42, compensated. Therefore, in this circuit, the value of the resistor 51b must be selected for the value of the potentiometer 44 so that the change in the supply voltage is divided into one-fifth to sixth by the input 41a of the amplifier 41. It should also be noted that the Zener diode 43 parallel to the potentiometer 44, the presence of which is required independently of the invention, does not prevent compensation from occurring. In such a circuit, a perfect compensation was achieved by selecting the value of the potentiometer 44 at 10 kOhm, the resistor 45 connected thereto to 1.5 kOhm, the Zener diode 51a for ZY-120 and the resistor 51b at 8.2 kOhm.

Since the input 41a of the amplifier 41 is directly coupled to the power terminal 21 via the resistor 51b and the Zener diode 51a, the temperature dependence of the Zener diode 51a must also be considered. The temperature coefficient of the Zener diode about 100 V used in the circuit of FIG. 2 is 0.11% / ° C. With such a Zener diode, incorporating the circuitry of the invention into a device and subjecting the device to a temperature change of 15 ° C, the change in image size is less than 2%, which is an accepted value. Of course, other types of device may require snow compensation, which can be achieved by using a NTC resistor connected in series or parallel to the Music Diode 51a.

Instead of the Zener diode, several lower-voltage, series-connected Zener diodes can be used, as well as any circuit arrangement that couples the voltage change of the power terminal 21 to the input 41a of the amplifier 41. Such a circuit may be, for example, the embodiment of Fig. 5, wherein the resistor divider 53a coupled to the power terminal 21 divides the voltage change and the coupled operational amplifier 53b amplifies the distributed signal to the required input at the amplifier 41a.

Likewise, the divider of Fig. 4 may be solved by a current generator 52b made of an active element and an impedance adapter 52c having an emitter follower also connected to the divider. The pitch required for compensation can be set by the resistors 52a and 52d.

The method and circuit arrangement of the present invention can advantageously be used to eliminate image size changes caused by audio change in all color television sets with active East-West raster correction.

Claims (7)

1. A method for eliminating volume-dependent image size changes of 110 ° color TV sets, in particular for use in high-sound power compositions, wherein the circuitry of the device is operated from power supplies stabilized by a switching power supply and the 110 ° picture tube cushion is active characterized in that the horizontal dimension change due to the supply voltage change of the horizontal diverting circuit (2) is compensated for by adjusting the horizontal size via a signal obtained from the supply voltage change of the horizontal diverting circuit (2) via the east-west raster correction circuit (4). 2. Circuit Arrangement to Eliminate Volume Dependent Image Size Changes of 110 ° Color TVs, Especially for Use in High-Volume Devices, comprising a Switch Mode Stabilized Power Supply, a Horizontal Deflection Circuit and a Vertical Deflection Circuit, and a Horizontal Deflector Circuit and the east-west raster correction circuit has an amplifier characterized in that between the power terminal (21) of the horizontal diverting circuit (2) and the input (41a) of the amplifier (41a) of the east-west raster correction circuit (4), optionally a diode (46) - a compensation network (5) is installed. HU 200049 A The circuit arrangement according to claim 2, characterized in that the compensation network (δ) consists of a passive compensation network (51) comprising at least one Zener diode (51a) and a resistor 5 (51b) connected in series with each other. Circuit arrangement according to claim 3, characterized in that a 10 NTC resistor (51c) capable of compensating for the temperature change is connected in series and / or parallel to the Zener diode (51a). Circuit arrangement according to claim 2, characterized in that the compensating network (5) comprises a current generating active compensating network (52) having a current generator (52b) and a resistor (52a) connected in series with a resistor (52a) between its input and ground. 52d) is connected, and the common point of the resistor 52a and the current generator 52b is connected to the output of the active compensator network 20 via the impedance adapter 52c. Circuit arrangement according to claim 2, characterized in that the compensation network (5) is formed by an operational amplifier active compensation network (53) having a resistor divider (53a) coupled between its input and ground, and an active amplifier network (53b) is connected between its output 531 and its output 531, with variable gain amplification (53b). 7. Circuit arrangement according to any one of claims 1 to 3, characterized in that the power supply terminal (31) of the vertical diverting circuit (3), 35 or at least the sliding circuit (32) is connected to a rectifier (23) connected to a series transformer coil (22) of the horizontal diverting circuit. 40