DE2428332C3 - Circuit arrangement for dynamic convergence correction - Google Patents

Description

The invention relates to a circuit arrangement as it is assumed in claim 1.

The three electron beams of a picture tube used in a color television receiver must converge at all points on the screen of the tube so that no undesired color fringes appear in the television picture displayed. Because of the specific geometric relationship between the beam deflection / .entrum and the screen, rays which converge at the screen center suffer over-convergence when they are deflected towards the edge regions of the screen. This is because the distance from the beam deflection center to the relatively flat screen increases as a function of the beam deflection angle with respect to the screen center. In color picture tubes in which the electron guns are arranged in a triangle (delta arrangement), the electron beams are usually brought to convergence at the center of the screen by adjusting the position of permanent magnets in the area of the tube neck where the beams leave the beam generation system , are arranged around the outside of the glass bulb of the picture tube. In addition to these so-called "static convergence correction" nor measures to bring about the "dynamic Konve are gence ^r: <required so that the beams converge at all other points of the screen. The dynamic convergence is usually achieved with the aid of electromagnets which are arranged at a mutual angular distance of 120 ° around the tube neck and whose coils are supplied with electrical currents of a suitable shape. The electromagnets excite pole pieces located inside the tube to magnetically affect each of the electron beams to achieve convergence.

Usually the comfort bobbins are used for the Red ray and, for the green ray, currents of a suitable waveform with vertical and horizontal frequency fed. The convergence magnel for the blue ray usually only receives currents with horizontal frequency, because the blue ray is in the middle between the red ray and the green ray and in many cases only a convergence correction in the vertical direction is required. As a result of advancing technology and the relatively large deflection angle (e.g. 110 °), with which the color picture tubes contained in today's television receivers work, it becomes more difficult to obtain one Achieve convergence of rays at all points on the screen. It is therefore often necessary also modulate the horizontal frequency convergence correction current door the blue beam in such a way that changes its amplitude according to requirements at different points on the screen. It is known, that by vertical frequency modulation of the horizontal frequency signals the appropriate waveform can generate for the total convergence current of the blue convergence coil.

It is desirable to have the required degree of modulation in modulating the horizontal convergence current with a vertical frequency waveform by means of a relatively simple yet effective one To achieve circuit. A so-called "active" circuit that is used to achieve a degree of modulation for example 30% several transistors including one or more expensive power transistors contains is not economical. If, on the other hand, one modulates with a "passive" Convergence circuit performs in which the horizontal convergence flow through non-active elements

ι ί

is shaped, then it is not possible to achieve the required degree of modulation or the amplitude modulate the convergence current without distortion.

From the magazine "Funkschau", 1973, issue 4, pages 111 to 113 is an arrangement? For the production of a line-frequency sawtooth oscillation by adding a line-frequency sawtooth to an inverted one Sawtooth and a distorted pulse. According to FIG. 7, which the in F i g. 6 shown in more detail Convergence circuit indicated by a box is to the first, horizontal frequency signal source and to the Convergence coil no integrator connected. The magazine "Funkschau" 1973, issue 5, pages 159/160 shows in FIG. 9 to 11 circuits in which several Input signals are damped and combined to form a convergence oscillation. According to FIG. 11th use is made of a predistortion of the line pulses, and besides these predistorted ones Line pulses, the circuit requires a line-frequency sawtooth oscillation, which with the pulses is combined. The amplitude modulation of the saw teeth carried out in the known cases requires additional isolation between the modulator and the sawtooth source, and this isolation must be used Resistors used, which cause undesirable losses.

From the "Technischen Mitteilungen der AEG-TeIefunken" iahrgang 1962 (1972) issue 3, ropes 107 to 112 is known by Fig. 12, a circuit in which an unspecified output signal of a Hori zontalkonvergencegenerators with the help of a vertical frequency parabolic form of an absorption modulation is subjected. The resulting signal is fed to the convergence coil via an amplifier. the Horizontal convergence vibrations are generated by the horizontal convergence generator through a resistor supplied, in which power losses also inevitably occur. If you choose this resistance low in the sense of smaller losses, then less power is implemented in it, but it then isolates no longer the convergence generator against the impedance changes caused by the amplitude modulator. On the other hand, if the resistance is made large for reasons of this isolation, then it increases accordingly also the losses.

The object of the invention is to provide a relatively simple dynamic convergence circuit, with which a sufficient modulation without undesired distortion is largely loss-free the waveform of the current flowing through the convergence coil can be achieved. This task will solved by the characterized in claim 1 invention.

In contrast to the circuits known from the "Funkschau", the invention only requires the line return pulses that are already present and the image deflection oscillation that is also present. This To reduce ohmic losses, both signals are practically only generated with the aid of reactances processed so that the inventive f> o Modulator works with very little loss. Neither of these references gives an indication of the advantages of the in the circuit according to the invention applied double integration of the line-frequency pulses (namely once by the first integrator and on the other hand by the convergence coil itself) and the Coupling of an absorption modulator between the integrators. In this way one becomes at the same time Isolation between modulator and pulse source is achieved and losses are kept low. An extremely Furthermore, the circuit according to the invention is less complex and expensive. from the fact that they are circuit elements takes advantage of the prior art for improving the parabolic shape anyway are. The article in the "Funkschau" mentioned in the second position is more suitable for the expert from the Invention to lead away, since it is based on the line-frequency sawtooth oscillation, but not from one Pulse (namely the return line pulse), like the Invention. For isolation between the absorption modulator and the line-frequency vibration source the invention uses an integrator whose connection facing away from the signal source to the modulator connected is. However, the integrator essentially contains reactances and is thus largely lossless. In contrast, the circuits according to "Funkschau" contain practically no essentials at all Reactances, so that the low losses achieved in the invention are not achieved, which are the result result that, according to the invention, a pulse is assumed which integrates into a sawtooth which is fed to the convergence coil and is integrated again by this to form a parabola.

The invention is explained in more detail below with reference to an embodiment shown in the figures.

F i g. 1 illustrates how misconvergence of three electron beams on the screen of a Color picture tube expresses;

Fig. 2 shows partly in block form and partly as Detailed circuit diagram of an embodiment of a dynamic convergence circuit according to the invention;

F i g. 3a and 3b show waveforms for the convergence coil as it would be with the circuit of FIG. 2 can be obtained.

In FIG. 1 shows how a misconvergence of three electron beams occurs on the screen a color picture tube expresses. The screen 10 has a horizontal axis 14 and a vertical axis in the drawing Assigned to axis 15. The three grid lines 11, 12 and 13 represent three lines, as they arise when the green steel, the red ray and the blue ray across distracting the screen. Ideally, that is, if the rays converged properly, would all three lines 11, 12 and 13 coincide. In Fig. 1, the three lines are for illustration shown completely separated from each other, but in reality the green line 11 and the red line are located Line 12 together, while the blue line 13 is in the center of the screen at the location of the vertical axis 15 touches the other lines. The problem with the case shown in Fig. 1 is a so-called "over-convergence" the blue line 13 on the right and left edge. To get convergence, therefore, one must provide a circuit which makes the edges of the blue line 13 converge so that the three lines at all Points of the screen are essentially convergent. The misconvergence shown in FIG. 1 occurs a picture tube, which has a relatively large deflection angle and in which the electron guns a Form a delta arrangement. The misconvergence expressed in the blue line 13 is at the upper end of the Screen 10 strongest and decreases towards the horizontal axis 14 at the center of the screen. If you are the The convergence coil for the blue beam supplies a generally parabolic waveform, then im

generally established the convergence for the blue beam. For picture tubes with a large deflection angle however, this waveform may cause the blue beam to be near the top of the Over-converged on the screen. Since, as mentioned, the conditions leading to the misconvergence increase with increasing Distance from the horizontal axis 14 becomes more pronounced, the parabolic waveform of the Modulate the horizontal frequency convergence correction signal so that its amplitude is at the upper edge of the Screen is smaller than in the middle.

The F i g. 2 is the circuit diagram of an embodiment of the dynamic convergence circuit according to the invention; with which the overconvergence of the blue beam shown in FIG. 1 is corrected. the The convergence circuit of Figure 2 receives vertical rate input signals from a vertical deflection stage 16 and horizontal rate input signals from a horizontal deflection circuit 31.

In the vertical deflection stage 16, a suitable vertical driver stage 17 is coupled to the base electrodes of two vertical end transistors 18 and 19 connected in series with one another. The transistors 18 and 19, the main current paths of which are in series with one another between a voltage source B + and ground, form an ordinary push-pull amplifier. The common connection between the two transistors, which forms an output terminal, is connected to ground via two deflection coils 20 and 20a connected in series and via an S-shaping capacitor 21, which also serves as a direct current block, and a resistor 22. Resistor 22 can have a relatively small resistance and is used to generate a feedback signal for the deflection stage. The feedback circuit is not essential to the operation of the present invention and is therefore not shown in the drawing. In operation, vertical deflection stage 16 provides a sawtooth voltage 23 at the junction between capacitor 21 and resistor 22 during each vertical deflection interval. The portion of the sawtooth rising linearly in the positive direction provides the current through the vertical deflection coil which is required to deflect the electron beam from the top to the bottom of the screen during the trailing portion of each vertical scanning interval. The part of the sawtooth 23 going in the negative direction represents the return part of each scanning interval, during which the electron beams are quickly brought back to the upper edge of the screen in order to be ready for the next scanning interval.

The connection point between the capacitor 21 and the resistor 22 where the sawtooth wave 23 is derived is connected to a red vertical convergence circuit 25 and to a green vertical convergence circuit 26. These two convergence circuits 25 and 26 give the sawtooth shaft 23 the appropriate shape so that a desired convergence current flows in each of the convergence windings 27 and 29 of the associated convergence magnets 28 and 30 for the red beam and the green beam.Conventional circuit arrangements can be used to achieve these functions.

One connection of the horizontal deflection circuit 31 is connected to a red horizontal convergence circuit 32 and a green horizontal convergence circuit 33. These two circuits give the waveforms coming from the deflection circuit 31 the appropriate shape so that a suitable convergence current flows through the windings 34 and 35 of the associated convergence magnets 28 and 30 for convergence correction of the red beam and the green beam.

s The circuit arrangement described so far can be conventional and provides the necessary correction currents for the convergence of the red ray and the green ray both in the horizontal direction as well as in the vertical direction.

ίο The connection point 24 is via a variable Resistor 45 connected to the emitter of a transistor 46. Two resistors 47 and 48 are in series connected to each other between a voltage source + V and ground. The connection point between the Resistors 47 and 48 bias the base of transistor 46. The collector of the Transistor 46 is connected to the winding of a resistor 49 and a diode 50 polarized as shown Convergence coil 42 connected.

A pulse 36 coming from the horizontal deflection circuit 31 passes through a capacitor 37 and a variable inductance 38 to a connection of a network, which consists of the parallel connection an inductor 39, a capacitor 40 and a resistor 41. The other end of this Parallel connection is connected to the convergence winding 42. A series connection of a capacitor 43 and a damping potentiometer 44 lies parallel to the convergence coil 42 and forms with this a resonance circuit.

In operation, the negative horizontal frequency pulses 36 via the capacitor 37 and the for Amplitude adjustment serving inductance 38 to the parallel connection of the inductance 39, the capacitor 40 and the resistor 41 given and integrated there. The resulting waveform becomes then placed on the convergence coil 42, where it is further integrated, so that a parabolic Waveform arises as it does with signals 61 and 62

in Fig. 3b is shown. This part of the circuit arrangement generates a parabolic current wave in the convergence coil 42 for convergence correction by double integration of horizontal-frequency pulses. As stated above, it is necessary to modulate the amplitude of this parabolic convergence current wave in order to eliminate over-convergence of the blue beam (which is expressed in the manner shown in FIG. 1).

The sawtooth shaft 23 obtained at the terminal 24 becomes

applied to the emitter of transistor 46. The transistor 46 is arranged as an amplifier in a common base circuit. The conductivity of the transistor 46 depends on which polarity and which amplitude the sawtooth wave 23 with respect to the bias voltage at the base of the transistor

stors just hat The transistor is biased during the negative part of the sawtooth wave 23 in the forward direction. In this conductive state, the conducts Transistor 46 current from convergence coil 42 through diode 50 and resistor 49 when diode 50

by the positive peaks of those shown in Fig.3b Parabolic wave is stretched in the forward direction.

When transistor 46 conducts then it forms one variable shunt load for the horizontal frequency parabolic convergence current. the

Variable resistor 45 specifies the degree of modulation by the measure of the conductivity of the transistor

46 determined. By dimensioning the resistor

47 lets the time be within the period of

923

Define vertical deflection shaft 23 during which transistor 46 conducts and a load for the convergence coil 42 represents. For example, if the overconvergence shown in Fig. 1 only in the upper third of the Screen is present, then the resistor 47 is chosen so that the transistor 46 only during the first third of the saw tooth 23 can be conductive. The degree of modulation during this interval can can be adjusted by adjusting the resistor 45, for example from about 5% to about 40%. the Resistor 49 limits the maximum value of the current that can be conducted by transistor 46, whereby an upper Limit for the degree of modulation formed and the transistor from damage due to overcurrent is protected.

FIG. 3 a shows the modulation envelope of the horizontal-frequency parabolic waveform 60 over an entire vertical deflection period. In FIG. 3a one recognizes that the energy of the horizontal frequency Component is decreased during the first third of the vertical deflection interval and that the Modulation in the form of a sawtooth wave 23 of FIG. 2 corresponds.

A main feature of the convergence circuit according to the invention is the DC coupling of the den Transistor 46 containing shunt loading with the convergence coil 42. This coupling is with the Resistor 49 and diode 50 reached. The diode 50 provides a DC component when used during the positive parts of the horizontal frequency convergence current conducts, and this direct current component changes the mean value of the parabolic current wave flowing through the convergence coil 42. In the Shaft 62 shown in FIG. 3b, which generates the parabolic convergence current flowing through the convergence coil without shunt loading, its amplitude ranges from -1 to + I2 · If the diode 50 conducts and the bypass path via resistor 49, transistor 46, variable resistor 45 and the resistor 42 is closed to ground, only the positive parts of the current wave work on load, as shown by waveform 61 in FIG. 3b is shown. Because the mean value of the waveform to the same extent As energy is passed through diode 50, this change in average DC current is used in addition, the negative peak value of the "burdened"

Parabolic wave 61 to substantially the same value like the negative peak value of the "unloaded" parabolic wave 62. This has the advantage that the The electron beam in the central area of the screen around the vertical axis 15 of FIG. 1 does not is moved. Since the current through the convergence coil is only attenuated at the edges of the grid, which correspond to the positive peaks of the horizontal frequency parabolic current becomes the overconvergence of the beam is corrected at the edges, while the beam in the central part of the raster is essentially corrected remains unaffected.

As mentioned above, the resonance frequency of the with the convergence coil 42, the capacitor 43 and the damping resistor 44 formed resonance circuit at the horizontal scanning frequency. Even if the diode 50 and the transistor 46 are conductive, will therefore the parabolic course of the waveform is not distorted by the direct current load, since the relative high Q value of the resonance circuit maintains the desired parabolic shape.

Since the diode 50 only allows current to pass in one direction, the active element in the shunt load, that is to say, the transistor 46 can also be an element which is conductive in one direction, for example an in transistor operating normally. Because the transistor works in normal operation, its Conductivity easily controlled over the full range from the blocking state to the saturation state thereby creating a strong modulation wave, that is, the sawtooth wave 23, within this range can be delivered. In addition, the transistor 46 can be designed for relatively low powers be small signal transistor, which reduces the cost of the circuit arrangement.

If a positively rising sawtooth 23 is not available, a negative can also be used in its place going sawtooth can be used if you put this sawtooth on the base of the transistor and connects potentiometer 45 to ground instead of terminal 24. It should also be noted that the The illustrated modulating waveform 23 need not be limited to a sawtooth, but exactly may well be any suitably graded waveform occurring at vertical deflection frequency.

1 sheet of drawings

109 611/33!

Claims (5)

Patent claims: 1. Circuit arrangement for dynamic convergence correction with a convergence coil and with a first and a second signal source, the Vibrations of a first or second waveform with a first or second frequency deliver, further with an absorption modulator, which is a first active, of the two vibrations controlled and the amplitude of the first oscillation according to its conduction state contains modulating current control element, characterized in that to the first Signal source (31) and a first integrator (39, 40, 43, 44) connected to the convergence coil (42) is, to whose terminal facing away from the first signal source the modulator (46, 49, 50) is connected is. 2. Circuit arrangement according to claim 1, characterized in that the first integrator (39, 40, 43, 44) in series with the first signal source (31) and the convergence coil (42), the parallel connection of a first capacitance (40) with an inductance ( 39) and that the series connection of a second capacitance (43) with a first resistor (44) is connected via the convergence coil (42). 3. Circuit arrangement according to claim 1, characterized in that the first active current control element (46) has an input, an output and a reference electrode and that the modulator has a second resistor in series with a component (50) which is current-permeable only in one direction (49), which is connected between the connection point of the convergence coil (42) with the first integrator (39, 40, 43, 44) on the one hand and the output electrode (collector of transistor 46) on the other hand, that the reference electrode (base of transistor 46) to a reference voltage source (47, 48) and that the capture electrode (emitter of transistor 46) is connected to the second signal source (16). 4. Circuit arrangement according to claim 3, characterized in that the through a diode (50) formed only in one direction current-conducting component in the same direction as the main current path of the active Sirom line element (transistor 46) is polarized. 5. Circuit arrangement according to claim 1, 2 or 3, characterized in that the active current control element is a transistor. whose entrance, The output and reference electrodes are the emitter, collector and base, respectively. 5. Circuit arrangement according to one of the preceding claims, characterized in that a damping reactance between the first integrator (39, 40, 43, 44) and the first signal source (31) (38) is connected that the vibrations supplied by the first signal source (31) with Line frequency occurring line return pulses and that the from the second signal source (16) The vibrations supplied with the frame rate are vertical sawtooth vibrations.