DE2130542A1 - Circuit for supplying a deflection coil for a cathode ray tube, especially for vertical deflection, with four output stage transistors forming a bridge circuit - Google Patents

Description

Circuit for feeding a deflection coil for a cathode ray tube, especially for vertical deflection, with four forming a bridge circuit Output stage transistors As the cathode ray tubes used in television receivers, for example not without certain tolerances with regard to the arrangement of the systems for the beam generation can be manufactured, one is forced to provide means with which after em Assembling a television receiver to set the correct position of the picture can. With black and white receivers you have to correct the vertical image centering as is known, permanent magnets are used. For color television receivers with three cathode ray systems these measures cannot be applied in a satisfactory manner because Here there is a mutual influence between the mentioned magnets and different ones other correction magnets, e.g.

would give the color purity magnet. It is therefore well known has been proposed (DU-PS 1 028 700) to center the vertical central position of the electron beams a direct current of adjustable strength and selectable Direction to pass through the vertical deflection coils.

The ones known from tube circuits for vertical deflection Circuits cannot be easily applied to circuits that only use Transistors work. This is especially true for transistorized ironless circuits.

With a known ironless circuit for vertical deflection (DAS 1 289 098) the deflection coil is connected to the Output stage transistors coupled. The coupling capacitor is required to the Deflection coil from the direct current flowing through the output stage transistors, its Size depends on several disruptive factors, to be separated and first of all to gain a direct current-free deflection current. For subsequent correction of the Image centering in the vertical direction could be thought of using the deflection coil the necessary for the correction via a direct current source connected in parallel to it Direct current to impress. To the output stage transistors but not through the parallel to unnecessarily load or not to load the direct current source connected to the deflection coil in this way the deflection current through the coil would have to be reduced of the correction direct current via a ratio in relation to the direct current resistance of the Deflection coil made of great resistance. However, this would result in an unacceptable power loss mean.

The expense for a direct current source would also be disadvantageous selectable polarity.

Another ironless circuit for vertical deflection is known (Messages from the application laboratory, Valvo, 14.4.70), where the Output stage made up of two complementary output stage transistors connected in series consists. The two output stage transistors are between two voltage points connected with different polarity with respect to the reference voltage.

The deflection coil is between the connection point of the two output stage transistors and the reference voltage switched and galvanically connected to said points. A correction of the vertical centering of the image, i.e. a shift in the center of the image perpendicular direction, happens because the operating points of the two output transistors simultaneously to be changed. The disadvantage of this circuit is that it has two power supplies for the two voltages of different polarity are required.

The invention is based on the object of an ironless circuit to create for the vertical deflection, which is simply structured and which does the named Avoids disadvantages.

The invention relates to a circuit for feeding a deflection coil for a cathode ray tube, especially for vertical deflection, with four output stage transistors, two of which are connected in series with each other and one of the two branches form a bridge circuit, the deflection coil between the two connection points is arranged by two output stage transistors located in a bridge branch. It is known (Electronics 1954, page 176 to page 179), one of four tubes to provide formed bridge circuit for a deflection circuit. This known circuit but gives no indication of how to solve the problem on which the invention is based. The circuit according to the invention is characterized in that for each bridge branch a driver transistor is provided, the collector of which is galvanically connected to the base of the one output stage transistor and its emitter galvanically to the base of the other Output stage transistor of this bridge branch is excluded, and that the base connections of the driver transistors to a potentiometer containing and designed in this way Voltage divider network are connected that a shift of the potentiometer tap the base biases of the two friction transistors changed in opposite directions.

So you come along with, for example, to correct the vertical centering of the image a single potentiometer which only consumes a small amount of power loss, and one needs only a single power supply.

In a further development of the invention, the output stage transistors, whose base connections are each connected to the collector of a Teibertransistor are operated as a switch. Correspondingly, in another further training of the invention, the output stage transistors, whose base connections each to the emitter a driver transistor are connected, operated as a switch. The voltage divider network consists in an advantageous embodiment of the invention of two between the poles of an operating voltage switched voltage dividers, wherein at least a part of the one voltage divider from the between the one end terminal and the Tapping the potentiometer lying resistance and correspondingly at least one Part of the other voltage divider from that between the other end terminal and the Tap of the potentiometer lying resistance exists. The tap of the potentiometer is in particular via a variable resistor to one pole of the operating voltage connected.

The invention is based on an embodiment shown in the drawing is illustrated, explained. 1 shows an exemplary embodiment of the invention and FIG. 2 shows the voltage profiles occurring at individual points in the circuit according to FIG.

In Fig. 1 is an embodiment of the circuit according to the invention shown. The sawtooth shape required to control the output stage Control voltage is obtained in a known manner from a synchronized sawtooth generator The output of this generator 1 is connected to the base of a transistor 3 connected, which together with the resistors 2 and 4 forms an inversion stage. above the capacitors 5 and 6 are from the collector and from the emitter of Transistor 3 tapped two control voltages that are in phase opposition to each other. These two control voltages each control a driver transistor 7 and 15 at its base. The driver transistor 7 is used to control the of the two Output stage transistors 10 and 11 formed branches of a bridge circuit, wherein the one connected to the positive operating voltage source 25 via the resistor 8 Collector of driver transistor 7 with the base of output stage transistor 10 and the emitter connected to the reference voltage via the resistor 9 to the base of the output stage transistor 11 is connected. The collector of the output stage transistor 10 is connected directly to the positive operating voltage 25. Its emitter is connected to the collector of the second output stage transistor 11 of this bridge branch. The emitter of the output stage transistor 11 is connected to ground via the resistor 20.

he second branch of the bridge circuit forming the output stage consists of the two output stage transistors 13 and 14, which correspond to the above explained first bridge branch of one of the driver transistor 15 and the resistors 16 and 17 existing driver stages can be controlled.

The two bridge branches are on the one hand by the connection 37 of two emitters of the output stage transistors 11 and 14 and on the other hand through the common Connection of the collectors of the output stage transistors 10 and 13 to the operating voltage 25 connected to each other. The load on this output stage, which is designed as a bridge, the vertical deflection coil 12 is between the two circuit points 38 and 39 switched, in each of which the two output stage transistors forming a bridge branch 13 and 14 or 10 and 11 are connected to each other. (If necessary, between the points 38 and 39 on the one hand and the transistors on the other hand resistors).

For setting the direct current ratios in the bridge circuit a potentiometer 21 is provided, the end connections of which on the one hand via the resistors 19 and 23 to the operating voltage 25 and on the other hand via the two resistors 18 and 24 are connected to the base connections of the friction transistors 15 and 7. Via the adjustable resistor 22, the tap of the potentiometer 21 is connected to ground connected. This determines the position of the tap on the potentiometer 21 the operating points of the driver transistors 7 and 15 so that when adjusting the Tap the two working points are changed in opposite directions. With the changeable Resistance 22, the above-mentioned working points can be changed evenly.

Since the output stage transistors of the two bridge arms are each galvanic are connected to the driver transistors 7 and 15, the DC current ratios the bridge circuit from the direct currents flowing through the driver transistors 7 and 15 and thus also determined by the position of the tap of the potentiometer 21.

The operation of the circuit described so far in relation to the The sawtooth-shaped control voltage generated by the generator 1 is explained as being large Part already from the voltage curves shown in Fig. 2 at the corresponding Circuit points in FIG. 1. One recognizes from the profile of the voltages at the circuit points 31 and 32 that the two driver transistors 7 and 15 are driven in phase opposition.

If, for example, during the first half of the period of the Control signal appearing on line 30 at the base of driver transistor 7 positive control signal (voltage curve 31) appears, this has according to the Voltage curves at points 35 and 36 result in the Output stage transistor 10 is blocked, while the output stage transistor 11 with a with respect to the Emitter positive base voltage is controlled so that the current flowing through it from a maximum value at the beginning of the period of the sawtooth control signal falls to zero towards the end of the first half of the period. During the described The driver transistor 15 is given a negative control signal (voltage curve 32) controlled and thus blocked. This has according to the voltage curves at points 33 and 34 result in the output stage transistor 13 reaching saturation is conductive, while the output stage transistor 14 is blocked. The during the The current flowing through the deflection coil 12 thus flows from the described period of time the voltage source 25 through the output stage transistor operating as a closed switch 13, through the deflection coil 12, through the one with a sawtooth-shaped control voltage controlled output stage transistor 11 and via the resistor 20 to ground In the second half of the period of the sawtooth-shaped generated by the generator 1 Control voltage passes through the capacitor 6 to a driver transistor 15 that conducts current controlling positive control voltage to the base of this transistor while over the capacitor 5 a negative control voltage blocking the driver transistor 7 appears at its base. The explanation given above for the output stage transistors 13 3 and 14 formed bridge branch applies in this case, that is, for the second half of the period of the sawtooth voltage for the output stage transistors 10 and 11 existing bridge branch. The way in which the Output stage transistors 13 and 14 in this case as before those of the output stage transistors 10 and 11. This has the consequence that the current through the deflection coil 12 changes its direction has changed and now from the operating voltage source 25 through the output stage transistor 10 working as a closed switch, deflection coil 12, the controlled output stage transistor 14 and flows through the resistor 20 to ground. The voltage driving the deflection current through deflection coil 12 is given as the voltage difference occurring between points 38 and 39 according to the voltage curves shown in FIG.

With an exact adjustment carried out by means of the potentiometer 21 the bridge circuit, both bridge branches are controlled in the same way, see above that the current reversal of the deflection current flowing through the deflection coil 12 follows exactly half of the period happens.

The deflection current is then practically free of direct current.

About the unavoidable tolerances when installing the deflection system in a picture tube see B. a color television receiver conditional versohiebun3 the central position To be able to compensate for the image, the bracket circuit according to FIG. 1 is by means of of the potentiometer 21 detuned until the resulting direct current component of the deflection current the center of the image written by the electron beams in moves the center of the picture tube.

Depending on the direction in which the tap of the potentiometer 21 is about If the middle position is shifted, a positive or negative arises DC component of the deflection current. The image can therefore only be achieved by means of one Potentiometer 21 and without a particularly complex additional circuit in both directions corrected from the center line.

The example of the invention shown in FIG. 1 is not limited to one application for a vertical deflection coil. The circuit leaves are also good for the control of convergence coils. It is with that possible, omit additional coils for static convergence and static displacement to carry out via the coils for the dynamic correction.

Claims (7)

Claims 1. Circuit for feeding a deflection coil for a cathode ray tube, especially for vertical deflection, with four output stage transistors, of which two are connected in series with each other and one of the two branches is one Form a bridge circuit with the deflection coil between the two connection points is arranged by two end-stage transistors each lying in a bridge branch, characterized in that a driver transistor (7, 15) for each bridge branch is provided, the collector of which is galvanically connected to the base of one output stage transistor (10, 13) and its emitter galvanically to the base of the other output stage transistor (11, 14) of this bridge branch is connected, and that the base connections of the Driver transistors (7, 15) to a potentiometer (21) containing and designed in this way Voltage divider network (19, 21, 22, 23) connected. are that a shift of the potentiometer «tap the base bias of the two driver transistors (7, 15) changed in opposite directions. 2. Circuit according to claim 1, characterized in that the output stage transistors (10, 13), the base connections of which are each connected to the collector of a driver transistor (7, 15) are connected to be operated as a switch. 3. A circuit according to claim 1, characterized in that the output stage transistors (11, 14), whose base connections are each connected to the emitter of a driver transistor (7, 15) are connected to be operated as a switch. 4. A circuit according to claim 1, characterized in that the voltage divider network from two voltage dividers connected between the poles of an operating voltage consists, wherein at least a portion of the one voltage divider from between the one End connection and the tap of the potentiometer (21) lying resistance and accordingly at least part of the other voltage divider from that between the other end terminal and the tap of the potentiometer (21) lying resistance, and that the Tap of the potentiometer (21) connected to one pole of the operating voltage is. 5. A circuit according to claim 4, characterized in that between the tap of the potentiometer (21) and one pole of the operating voltage, a resistor (22) is arranged. 6. Circuit according to claim 5, characterized in that the resistor (22) is changeable. 7. A circuit according to claim 1, characterized in that between the base connections of the driver transistors (7, 15) and the voltage divider network a resistor (18, 24) is arranged in each case. Blank page i te