DE1257827C2 - CIRCUIT ARRANGEMENT FOR EQUALIZING THE GRID WRITTEN ON THE LIGHT SCREEN OF A CATHODE TUBE - Google Patents

Description

The invention relates to a circuit arrangement for rectifying the raster of a cathode ray tube written on the luminescent screen at the top and lower edge of the picture with a deflection system through which a deflection yoke is traversed by the horizontal deflection current Horizontal deflection coils and with vertical deflection coils through which the vertical deflection current flows and a magnetic component with a pre-magnetized three-legged core, the Middle limb of a winding fed with vertical deflection currents "and its outer limb are surrounded by a subdivided winding fed with horizontal frequency signals.

- That on the screen vain cathode ray tube As is well known, written grids can be influenced by factors Like the geometry of the deflection system, big one and the shape of the screen and its relative Abienkzehtfüm the electron beam as well as the parameters of the deflection circuit pillow or be distorted like a tart, ß with some devices such distortions can be eliminated by a static Körrektufändnüng, with others

ι »Devices such as television receivers with wide-angle baits Mehrstrählkäthöden-Bildröhfen, one has to apply a dynamic correction. It is already a circuit arrangement for equalization the electron beam of an image

tube by magnetic deflection in horizontal and vertical direction written on the screen Grid by applying a correctional tension, the vön dem döf in each case different direction of deflection corresponding deflection system

ao heads, known, in the parallel or in series

to at least one deflection coil at least one

Ablenkrichtüng an impedance is connected, the

Size with the detachment frequency of the other abb

. direction is varied. The impedance can be off

there are two coils, each with one of two further, with that of the 'other deflection direction Deflection system Connected / falling magnetically is coupled.

. When correcting a kissett-shaped Vefzeichen-

tion of the upper and lower borders of the grid must be periodic with the field frequency changing vertical deflection in the rhythm of the higher line frequency can be changed. Since the yertikälabienkstfom while. a period of

Line deflection currents are regarded as constant can, the compensation can only be poorly carried out in the rhythm of the line frequency Carry out a change in inductance in the vertical deflection circuit. Rather, Matt must be Vertikäläbienkström a KorrektürstrOffi with line frequency Add. This principle is taken from the essay "Experimental Color Television Circuits", issued June 1963 by the Philips Electronic Market Development Department, announced that a line-frequency correction current generated with the aid of a tube circuit is transformed into the Vertical deflection circuit is coupled.

The invention is based on the object of an operationally reliable and stable screen correction circuit specify which, with a simple structure, allows the correction of pillow or barrel distortions of the raster to be corrected without this requires changes to the circuit. This task is performed with a circuit arrangement of the type mentioned at the outset, according to the invention, in that the asymmetrical to the two outer biased leg split winding is the input winding and in such a sense of the horizontal deflection is traversed, that the magnetic generated by the two partial windings Rivers in the middle limb are opposite to each other and in the middle limb surrounding output winding connected in series with the vertical deflection coils as a result of the displacement the working point of the core due to the vertical deflection sawtooth current flowing through the output winding a line-frequency correction current with vertical position-dependent amplitude and

Induce polarity, which is also fed into the vertical deflection coils.

A capacitor is preferably connected in parallel with the output winding, which together with the The inductance of the output winding forms a parallel resonance circuit for the horizontal deflection frequency. Furthermore, preferably has the magnetization curve of the ferromagnetic core between areas of relatively higher and lower Permeability lying transition area, and the asymmetrical bias of the two outer ones Legs in the transition area are made by a magnet. Furthermore, the partial windings in Be connected in series with the horizontal deflection coils.

The invention is explained in more detail with reference to the drawing; it shows

F i g. 1 is a circuit diagram, shown partially in block form, of a television set with a circuit arrangement according to an embodiment of the invention,

2a and 2b are diagrams to explain the pillow-shaped or barrel-shaped distortion of a Raster,

. F i g. 3 is a graphical representation of the time course of currents, which in FIG. 1 shown Circuit arrangement flow,

F i g. 4 is a diagram showing the course of the signal caused by the steering in the input windings of the in Fig. 1 shows the magnetic amplifier generated magnetic flux,

F i g. 5 is a diagram to explain the bias flux generated in the core of the magnetic amplifier,

F i g. 6 is a diagram for explaining the magnetic flux generated in the core of the magnetic amplifier by the vertical deflection current;

F i g. 7 is a magnetization curve of the magnetic material from which the core of the magnetic amplifier is made,

Fig. 8 shows a hysteresis loop of part of the Core of the magnetic amplifier,

9 shows a hysteresis loop of another part of the core of the magnetic amplifier;

10 shows a hysteresis loop of a third part of the magnetic amplifier and

Fig. 11 is a partially shown in block form Circuit diagram of a television receiver with a circuit arrangement according to a second embodiment of the invention.

In Fig. 1, only those parts of a television set are shown which are necessary for understanding the invention, namely a cathode ray tube 10 with deflection coils 12, 14 or 16, 18 for deflecting the electron beam in two mutually perpendicular directions and a circuit arrangement 20, the supplies a deflection current I ₁ of frequency J ₁ to the coils 12, 14, and a deflection current I ₂ of frequency / ₂ to the coils 16, 18.

In Fig. 2a ein.Raster is shown, the upper and lower edge 22 recorded in a pillow shape s, ind. FIG. 2 b shows a grid with barrel-shaped distortion of the upper and lower image edges 24. The invention is based on the known object of eliminating these distortions, so that a practical rectangular grid with straight upper and lower edge 26 (Fig. 2a) and 28 (Fig. 2b) is created. The television set according to the invention shown in FIG. 1 serves to rectify the raster a magnetic amplifier 30. The magnetic amplifier has an input winding with two separate winding halves 32, 34, on outer legs 36 and 38 of a core 40 made of ferromagnetic material are arranged. The magnetic core 40 has two windows through the outer legs 36, 38 and a center leg 46 can be formed.

The series-connected winding halves 32, 34 are connected to a current source 42 which supplies the current I _{2 of} the frequency / _2. An output winding 44, which is connected in series with the deflection coils 12, 14, is arranged on the middle limb 46 of the magnetic core 40.

A bias flux is created in the magnetic core 40 generated by means of a permanent magnet 48, the

j, arranged in close proximity to the magnetic core 40 is. Instead of the magnet 48, an electromagnetic device for generating the Bias flux occur. A capacitor 50 is connected in parallel to the output winding 44, which will be discussed in more detail below.

To compensate for the raster distortions, the amplitude of the sawtooth-shaped current ^ of the field frequency is changed in the rhythm of the line frequency, as can best be explained with reference to FIG. In the upper part, FIG. 3 shows the course over time of the current I ₁ , the original trace part 52 of which (interval T _t ) is shown in dashed lines. The solid upper curve represents the course of the current I ₁ after it has been changed to rectify the raster. The changed current I ₁ contains an alternating current component 54, the amplitude of which continuously decreases between the beginning of the trace up to the point of intersection with the alternating current axis 56 and then increases continuously again after the phase reversal until the end of the trace. When the electron beam is deflected by the changed current I ₁ , the voltage shown in FIG. 2 a illustrated pincushion distortion compensated. The barrel-shaped distortion according to FIG. 2b can 'by reversing the phase position of the

AC component 54 can be corrected during trace intervals T _tx and T _t2.

How the present circuit generates the changed current I ₁ shown in FIG. 3 is now illustrated with reference to FIG. 4 to 10 explained.

The winding halves 32, 34 (FIG. 1) of the input winding are polarized in such a way that the magnetic fluxes generated in the magnetic core 40 exceed the values shown in FIG. 4 directions if the current I ₂ of frequency / ₂ (interval T ₂ ) at the point where the

drawn terminal flows into the winding 32. In this case, the lines of magnetic flux then run into the winding at the end marked with the dot and exit at the opposite end. The current in the winding halves 32, 34 generates in the magnetic core the one shown in FIG. 4, the respective magnetic flux Φ _{2 shown} , the components running through the center leg 46 canceling each other out. It is assumed that the winding halves 32, 34 fields are the same

magnetic field strength /? when the current I ₂ flows through them. The resulting flux Φ _τ only flows through the outer parts of the magnetic core.

Der'Permanentmagnet 48 generates a bias flux Φ ₆ , which the permanent magnet. 48 and the core sections 57, 58 containing magnetic circuit flows through, as shown in FIG.

Fig. 7 shows a magnetization curve of the ferro-

magnetic material of which core 40 is made. This curve comprises a section 59 with a relatively high permeability, a section 60 with a relatively low permeability and a transition section 62 lying between these, in which the permeability changes from a relatively high value to a relatively low value. The permanent magnet 48 generates a magnetic flux in the core sections 57, 58, the size of which is sufficient to set the magnetization of each of these core sections to a value in the transition section 62 of the magnetization curve. The permanent magnet also ensures that the same flux density is maintained in the core sections 57, 58, while the resulting flux in the central leg 46 of the core 40 is zero. When the amplitude of the current Z ₁ in Hinlaufabschnitt 52 during the positive half cycle increases (interval T _{1 2)} of WertO from, as in FIG. 3, this creates in the magnetic core 40 _ao an additional flow (Φ _1), as it is from Fig. 6 results. This flux Φ _{1 increases} the flux density in the core section 58, so that it is controlled in an area of low permeability, while the flux in the core section 57 _a § decreases and the operating point reaches the area of relatively high permeability. As a result of these permeability differences, a flux component Φ _{2 , generated by the current / 2} , occurs in the center leg 46, which induces a current of the frequency / _{2 in the winding 44.}

The capacitor 50 forms a resonance circuit with the resonance frequency / ₂ with the inductance of the winding 44. The current flowing in the resonance circuit has the form shown in FIG. 3, the alternating current component 54 shown. The voltage occurring at the capacitor 50 causes a current corresponding to the alternating current component 54 to flow in the deflection winding (12, 14) in addition to the current corresponding to the straight line 52. The flux generated by the current Z ₁ in the central limb of the magnetic core has opposite directions in the time intervals T _{1 t} and T _{t 2.} The phase of the alternating current component 54 therefore reverses in the middle of the trace interval.

The mode of operation of the present correction circuit can be further explained with reference to the hysteresis curves shown in FIGS. F i g. 8 shows the hysteresis curve of core portion 58 having a bias point 64; F i g. 9 shows the hysteresis curve of the core portion. 57, which has a bias point 66. As already mentioned, the resulting bias and control current flow in the center leg 46 is zero, and the bias points 64, 66 represent points of equal flux density. If the amplitude of the current I ₁ during the interval T _tt in the trailing section 52 decreases, the changes Flow in the middle limb 46 corresponding to the dashed hysteresis loop 67 in FIG. 10 from point 68 to point 70. In general, it is undesirable to drive the middle core limb into magnetic saturation. The center leg therefore has a high magnetic reluctance, e.g. B. an air gap so that the gj operating point runs through the hysteresis loop 67. Since f the core sections 57, 58 are premagnetized, ¹ the magnetic flux in section 58 selects

From the interval Tt ₁ to point 72 of the small hysteresis loop 73 in FIG. 8, while the flow in the core section 57 increases along the small hysteresis loop 74 up to point 75. Since the magnetic flux generated by the current I ₁ during the period T ₁₁ disturbs the equilibrium in the middle limb 46, one component of the flux Φ ₂ in the middle limb 46 (eg the flux from the core section 58) outweighs the oppositely directed flux component. Thus, along similar to the resulting flux in the center leg varies a small hysteresis loop of Schleife67 in Fig. 10 with the frequency f ₂ j Similarly, the flux changes in the center leg during the interval T _{t 2} (the area of the hysteresis loop from point 70 to point 76 ) with the frequency / ₂ by the oppositely directed changes in the flux Φ ₂ , since the flux in the core section 58 rises to the point 78 and in the section 57 falls to the point 80. These flux changes occurring at the frequency / ₂ in the center leg induce a current in the output winding 44, as has already been mentioned. The inductance of the winding 44 forms with the capacitor 50 a resonant circuit which is set to a desired frequency, e.g. B. frequency / ₂ , is tuned, and the oscillating current flowing in the resonant circuit causes a voltage to arise on the capacitor 50 which allows the additional alternating current component 54 in the deflection current flowing through the deflection coils 12, 14 to flow. Since the core sections 57, 58 are controlled by the flow _{generated by the StTOmZ 1} from the preload points 66 and 64 to the extreme values 80 and 72, the permeability of these core sections increases and, accordingly, the size of the component of the flow Φ ₂ in the middle limb increases during intervals T ₁₁ and T ₁₂ . The amplitude of the current induced in the winding 44 increases accordingly. The deflection current I ₁ thus contains an alternating current component during the trailing section 52, the amplitude of which increases from the alternating current axis of the current Z ₁ to both sides.

The barrel-shaped distortion shown in FIG. 2b can be corrected accordingly by reversing _{the polarity of the current Z 2.}

In Fig. 11, a television set is greatly simplified shown, which contains a circuit arrangement according to a second embodiment of the invention. The same parts are provided with the same reference numerals in FIGS. 1 and 11.

As usual, the television set contains a high-frequency amplifier, a mixer, an intermediate frequency amplifier, a video demodulator, a control circuit, a video amplifier and a sound section, which are shown schematically by a block 80. The video amplifier supplies a conventional signal mixture to an amplitude filter 82, which supplies a horizontal synchronizing signal to a horizontal deflection stage 90 and a vertical synchronizing signal to a vertical deflection stage 84 ^ The vertical deflection stage 84 has output terminals 86, 88, from which a deflection current Z _{1 of} the field frequency through the deflection coils 12, 14 flows.

The resonance circuit consisting of the inductance of the output winding 44 and the capacitor 50 is connected in series between the vertical deflection coils 12, 14. The resonance circuit 44, 50 is _{tuned to the frequency / 2 of} the horizontal deflection current Z.

An adjustable resistor 51 is connected in parallel to the resonance circuit, which increases the quality of the resonance circuit and thus to set the amplitude of the ac component 54 used for correction allowed.

To excite the resonance circuit 44, 50 and to modify the sawtooth-shaped vertical deflection current Z ₁ in the form shown in FIG. In the manner shown in FIG. 3, the winding halves 32, 34 of the input winding are connected in series with the horizontal deflection sinks 16, -18. The horizontal oscillating part, which comprises a horizontal oscillating element, a frequency regulating element and a horizontal adjusting element, supplies all the output terminals 92, 94 with a voltage that flows in the horizontal hinged sinks 16, 18 and the input winding 32, 34 of the magnetic amplifier 30, a saw-tooth-shaped current I _{2 of} the counters leaves. The halves 32, 34 of the input winding are designed so that they have a relatively small impedance for the current / line frequency during the transfer of energy of the horizontal deflection to the output winding 44. The magnetic amplifier 30 works otherwise as it is with reference to F ¹ i g. 1 was explained:

The described Korfektufschaltung can be modified according to the respective circumstances iti in the most varied of ways. The currents I ₁ Uhd / ₂ , which were assumed to be sawtooth-shaped, can therefore also have a different curve shape, and the corrective current superimposed on the herd _{part of the deflection current Z 1 can}

be influenced by changing the tuning of the resonance circuit.

Oils output winding 44 can consist of two bifilar wound winding parts connected in series, to increase the quality value of the starting circle. Another variation is the Output terminals 86, 88 of the vertical tray part 84 with a frequency tuned to the horizontal deflection Bridge series resonance circuit to shunt a low impedance for the over the winding 44 coupled Ströttikömportehte to create the line frequency and to disturb the Vertical oscillator circle by the line frequency impede.

In some cases, the length of the permanent magnet 48 used for premagnetization can be changed with respect to the core sections SI, 58 in order to adjust the compensation of the pincushion distortion at the upper and lower edge of the grid.

The pincushion distortion is not necessarily symmetrical about the center of the image. The amplitude the Kofrektüfschwingg can be changed by a Shunt to the permanent magnet 48 can be adjusted.

_a5 Instead of the series connection of the two holders 32, 34 of the first winding, one can also work with a parallel connection of these two winding halves in the same direction. The core sections 57, 58 can have a smaller cross-section than

the remaining parts of the magnetic core 40 of the magnetic amplifier.

1 sheet of drawings

309 616/463

Claims (4)

• ι patent claims: 1. Circuit arrangement for rectifying the raster of a cathode ray tube written on the luminescent screen at the upper and lower edge of the screen with a deflection system which has a deflection yoke with horizontal deflection coils through which the horizontal deflection current flows and vertical deflection coils through which the vertical deflection current flows, as well as a magnetic component with a pre-magnetized three-legged core, the center leg of which has one winding fed with vertical deflection currents and whose outer legs are surrounded by a subdivided winding fed with horizontal frequency signals, which means that the winding divided between the two outer, asymmetrically pre-magnetized legs (36, 38) is the input winding (32, 34) _{and the horizontal deflection current (Z 2} ) flows through it in such a way that the magnetic fluxes generated by the two partial windings are opposite to one another in the middle leg (46) and in which the m Ittleren leg (46) surrounding, in series with the vertical deflection coils (12, 14) connected output winding (44) as a result of the shift of the operating point of the core by the vertical deflection sawtooth _{current (Z 1} ) flowing through the output winding (44) a line-frequency correction current with vertical position-dependent amplitude and induce polarity, which is additionally fed into the vertical deflection coils (12, 14). 2. Circuit arrangement according to claim 1, characterized in that a capacitor (50) is connected in parallel to the output winding (44), which together with the inductance of the output winding (44) forms a parallel resonance circuit for the horizontal deflection frequency. __ 3. Circuit arrangement according to claim 1, characterized in that the magnetization curve of the ferromagnetic core is between Areas of relatively high and low permeability (areas 59 and 60, respectively) Transition area (62) has that the asymmetrical bias of the two outer Legs (57,58) in the transition area (62) by means of a magnet (48). 4. Circuit arrangement according to claim 1, characterized in that the partial windings (32,34) are connected in series with the horizontal deflection coils (16,18).