DE1931641C - Circuit arrangement for generating a line-frequency sawtooth current with field-frequency amplitude changes in a television display device - Google Patents

Description

The invention relates to a circuit arrangement for generating a line-frequency sawtooth current field-frequency amplitude changes in a television reproduction device, which arrangement with a line and a field deflection current generator for providing a line and field frequency, respectively Sawtooth current with almost constant amplitude to a line or partial image deflection coil and with a modulator controlled by the partial image deflection current generator for achieving the partial image frequencies Changes in amplitude of the zeilenfrequentcn sawtooth current is provided.

There is known a color television display apparatus, in the for color correction on the display screen of a picture tube in the device Line frequency sawtooth stream with itself with the partial frequency changing amplitude is used. From the beginning to the end of a run of the subframe sawzale stream should be the amplitude of the line frequency sawtooth correction current of a largest value decrease more or less linearly to zero, whereupon a more or less similar one Increase in the reverse current direction takes place. This correction current is applied to the line and / or field deflection coil flowing deflection current with almost constant amplitude superimposed, which current of 'learn line or field deflection current generator is fed to the relevant coil. The division of a deflection coil .ii two practically symmetrical reel halves attached to both sides of the tube of a picture tube in the display device creates the possibility of the correction current in one coil half of the deflection current with an almost constant To add amplitude and subtract it in the other half of the coil. The magnetic deflection field one coil half is reinforced in this way and that of the other coil half in almost weakened to the same extent. The effect is that the Correction current generates a magnetic quasi-four-pole field, which the normal, two-pole, the electron beam is superimposed in the picture tube deflecting magnetic field.

The magnetic quasi-four-pole field has the consequence that a circular or elliptical cross-section of an electron beam assumes a tilted elliptical shape. Several electron beams generated in the picture tube, the cross sections of which z. B. on one Circumference are, experience such a shift that they are on a tilted elliptical circumference reach. Because the so-called anisotropic astigmatism causes deformation similar to a deflection coil, which depends on the extent of the deflection, it is possible to do this by means of an oppositely directed deformation as a result of the mentioned correction current to fix.

It is also known to design the modulator as a multiplier, the information in relation to Line and field deflection current is supplied. In a further training of the multiplier »is a Arrangement has been specified in which the well-known Hall effect is used.

There are also circuits to correct the east-west or North-South-Rastervcr / errungPi! known, where the horizontal deflection current depends on the vertical deflection current or the vertical deflection current depending on the Horizonlal-Ah- '■' iikstmmes is changed, whereby the deflection currents, n the Abli'nk-TeiKniilen are iricich. M ei the IfMn On the other hand, additional correction currents are generated or applied to the coil halves for the Horizontal deflection according to the so-called differential current control in each case in the opposite direction flow through, so that the currents in the two horizontal deflection sub-coils are unequal. Durcli corresponding weakening and amplification of the magnetic deflection field results in a quasi-quadrupole deflection field.

ίο The invention aims to provide a circuit arrangement, especially for the correction of the corner convergence, in which the modulator is very simple is formed, with a large field-frequency amplitude change of a without interference line-frequency sawtooth current is achieved. A circuit arrangement according to the invention is therefore characterized in that the modulator is an electronic one which switches at the line frequency Contains switch that during the trace time of the line deflection current generator to the line deflection coil supplied sawtooth current the Teilbildablenkstromgenerator, which is one with the Supplying voltage that changes field frequency, connects to an oscillating circuit that is connected in parallel a capacitor and a line or Sub-image deflection coil comprehensive inductance contains, whereby the period of the resonance frequency of the oscillation circuit is almost twice that of Ramp-down time of the line frequency sawtooth deflection current is.

Another embodiment of the circuit arrangement according to the invention is characterized in that the inductance of the resonant circuit with at least four arranged in a bridge circuit inductive components is provided, two of which by the consisting of two coil halves Line or field deflection coil are determined.

A circuit arrangement according to the invention also enables part of the deformation fix that as so-called pincushion distortion in a grid on the screen of a picture tube Black and white or color television display device occurs.

The pincushion distortion is caused by the slight curvature of the screen surface of the picture tube and caused by the magnetic field distribution in the line and Tcilbildablcnkspulen. The point of impact of an electron beam on the screen is at a larger deflection angle and thus at a greater distance to be covered by the electrons, depending on the extent of the deflection have an additional shift in the deflection direction. That extra shift, which takes place according to a parabolic function can be remedied by acting on a deflection current constant amplitude a correction current with oppositely directed parabolic shape as Function of time is superimposed. For the line break stream this results in a line frequency sawtooth drone, whose amplitude changes during the beat of a partial image period corresponding to a Parahclfunktion changes, in such a way that it reaches a maximum value almost in the middle of the stroke will. For a line deflection in horizontal rich hanging and a partial deflection in a vertical direction k.iim through the mentioned corrected line deflection line the so-called East-West-Rasterkorrek-111 r de: Kis' ■ Mvcr / eicliniiim can be achieved.

bine door assembly according to the invention for performing the east-west raster correction of the pincushion distortion on the screen of a picture tube is characterized in that in series with the circuit of the line deflection current generator and the Zcilenablenkspule a part of the inductance of the resonant circuit forming inductive component is provided.

The invention is explained in more detail using the figures, for example. It shows

Fig. 1 shows two embodiments of a circuit arrangement according to the invention, the two mentioned corrections by means of the line deflection coil (Church-run, which coil consists of two coils which are fed in parallel by the line deflection regenerator,

F i g. 2 a similar circuit arrangement as ι ι L '. 1 according to the invention, in which, however, the two S | uilenliften the line deflection coil through in series (I,: i line deflection current generator.

In Fig. 1, 1 ^{denotes a line and 2 a TViI 1} M '.Jablenkstromgenerator, which generators 1 and 2 can form part of a black-and-white or Γ rbfernsehen playback device. The line deflection generator 1, hereinafter referred to as k:; / with line generator 1, can be designed in a kücbiger manner and z. B. be provided with a resting or parallel savings circle. Furthermore, the line generator 1 for generating a high DC voltage can be designed as a flyback high-voltage generator. The partial image deflection generator 2, which is referred to below as partial image generator 2, can also be of a more or less common type, and the design is not essential for the invention.

The line generator 1 contains a transformer 3 which is provided with four windings 4, 5, 6 and 7. which are connected in series in pairs. These windings and the windings to be specified below all have the same winding direction, unless otherwise stated. The series connection of the windings 4 and 5 is connected to that of the windings 6 and 7 via a capacitor 8. The connection point of the windings 6 and 7 is connected to earth. The connection point of the windings 4 and 5 is connected to the cathode of a diode 9, the anode of which is connected to a terminal of a supply source (not shown) carrying a positive voltage + V _{s, the second terminal being grounded.} The diode 9 and the capacitor 8 form part of a series saving circuit.

The free end of the winding 4 of the transformer 3 is connected to a Ver-Mürkerclement 10 designed as a pentode, the cathode of which is geerilet. The control grid of the amplifier element 10 is grounded via a discharge resistor 11 and connected to an input terminal 13 of the line generator 1 via an isolating capacitor 12. The input terminal 13 of the line generator 1 is supplied with a control signal 14 for the periodic operation of the amplifier element 10. The control signal 14 has, as a function of the conductive, a periodic, pulse-shaped part for blocking the amplifier element 10 during a period of time AT ₁₁ and, according to the design of the transformer 3, a part that increases linearly during a period of time T ₁ /.

In the /.eilengcncrator I is by means of the control signal 14 milk'ls stray capacities of the transformer 3

Generates a voltage across the windings 6 and 7, which for the winding 6 at the connection point with the Capacitor 8 is shown with voltage 15 as a function of time. The free end of the winding 7 the transformer 3 carries a voltage equal to dio of voltage is 15, but of opposite polarity. This is due to + and - for the polarities of the above the windings 6 and 7 generated. Tensions indicated.

In order to generate a line frequency sawtooth current through any coil or set of sub-coils To generate an almost constant amplitude, which is denoted by / ',, at the voltage 15, it is sufficient that the Coil or the set of partial coils to the series connection of windings 6 and 7 of the line generator 1 to be connected. It is Z. B. possible, a parallel connection of a controllable, premagnetized Linearity coil 16 and a damping resistor 17 in series with the line deflection coil, which consists of two parallel-connected, almost symmetrical coil holders 18 and 19, directly to the line generator 1 to be connected. The coil halves 18 and 19 can still be divided into several sub-coils.

In order, according to a feature of the invention, to produce field frequency modulations, unequal line frequency sawtooth currents to be generated by the line deflection coil halves 18 and 19, these are in a bridge circuit recorded. The line generator 1 feeds the bridge circuit between the interconnected Ends of the coil halves 18 and 19 and the connection point of two nearly equal, series-connected windings 20 and 21 of a transformer 22, the connection point being the Coil half 18 and the winding 20 via a capacitor 23 to that of the coil half 19 and the Winding 21 is connected. The transformer 22 is provided with a primary winding, the two in series contains switched, almost identical windings 24 and 25, from which one taken from the partial image generator 2, voltage switched with the line frequency with the desired field frequency sawtooth change is fed. The use of the transformer 22 in a bridge circuit has the consequence that the line generator 1 and the field generator 2 do not interfere with one another via the transformer 22 be able. In order to reduce discharge fields and their leakage inductances, the windings 20, 21 and 24, 25 of the transformer 22 are wound bifilar.

In order to generate, according to a further feature of the invention, a line frequency sawtooth deflection current flowing through the two line deflection coil halves 18 and 19 with field frequency amplitude changes that run in almost the same direction for both halves, there is a supply point between a feed point of the aforementioned back circuit (18 to 23) and the line generator 1 a winding 26 of a transformer 27 is provided. Il The transformer has a primary winding 28 of a part of the image generator 2 removed, zeiienfrequenzmäßig switched voltage with the mentioned parabolic TRilbildfrequcnz change is supplied. In order to achieve a decoupling of the line generator 1 from the circuit containing the primary winding 28 of the transformer 27, a winding 29 of the transformer 3 is connected in series with the winding 28. This series connection, to which a con-

capacitor 30 is placed in parallel, the voltage taken from the "field generator 2" is supplied.

On orund of the field generator 2 and the voltage to be supplied by this with the required Field frequency changes are the two embodiments of a circuit arrangement according to the Invention described in more detail below.

The field generator 2 has a transformer 31, of which a primary winding 32 at one end with a terminal carrying the positive voltage + V and at the other end via an amplifier element 33 designed as a pentode and a parallel connection of a resistor 34 and a capacitor included in its cathode line 35 is connected to earth. A control signal 40 fed to an input terminal 39 is fed to the control grid of the amplifier element 33, which is designed as a pentode, via an isolating capacitor 36, a discharge resistor 37 to earth and a current limiting resistor 38. As a function of time, the periodic control signal 40 has a pulse-shaped part for blocking the amplifier element 33 during a time period Λ T _v and also a parabolic variable, linearly increasing part for controlling the amplifier element 33 during a time period / v

The transformer 31 has a secondary winding 41, via which a sawtooth voltage is generated by means of the control signal 40 using stray capacitances, not shown, of the transformer 31. The winding 41 is connected to a parallel circuit of two coil halves 42 and 43, which together form the partial image deflection coil. As a result of the high ohmic resistance of the field deflection coil halves 42 and 43, a field frequency sawtooth deflection current will flow through them. The forward or return time of the field frequency sawing deflection current with an almost constant amplitude, which is supplied by the field generator 2, corresponds to the time span 7 \ or 17 " _V in the control signal 40.

Under the influence of the control signal 40, a current which is composed of a parabolic variable and a linearly increasing current flows through the amplifier element 33 during the trace time of the partial image T _v. By specific dimensioning of the capacitor 35 and the resistor 34 of the parallel circuit in the cathode line of the amplifier element 33, a /? C time constant can be obtained, by means of which only an almost parabolic voltage is developed across the parallel circuit during the field trace time T _v. In order to achieve the east-west raster correction of the pillow twisting according to the invention, the almost parabolic voltage obtained must be fed to a modulator. For this purpose, the cathode of the amplifier element 33 in the form of a pentode in the field generator 2 is connected to the base electrode as an emitter follower via an isolating capacitor 44. npn transistor 45 connected. The collector electrode of the transistor 45 is connected to a positive direct voltage VJ at the terminal of a supply source (not shown), the other terminal of which is grounded. The terminal carrying the voltage VJ is grounded via series-connected resistors 46 and 47, the connection point of this series connection being connected to the base electrode of the transistor 45.

The emitter electrode of the transistor 45 is grounded via the parallel connection of a resistor 48 and a capacitor 49. As a result, the field generator 2 presses a during a field run time T _v Almost parabolic variable voltage 50 on capacitor 49. At voltage 50, the dashed line indicated by oV indicates the earth potential. This also applies to the voltage to be specified below. Dashed line without

ίο further designation indicates the average Value.

In the embodiment of a circuit arrangement according to the invention, this is the voltage 50 leading terminal of the capacitor 49 to a

ij circuit is connected which is constructed from the parallel connection of the capacitor 30 and the windings 28 and 29 in series with an emitter-collector circuit of a pnp-type transistor 51, the collector electrode of which is grounded. The transistor 51 is used

ίο as an electronic switch that switches at the time frequency and that can conduct electricity during the line delay T _1. For this purpose, a secondary winding of a transformer 52 is provided between the emitter and the base of the transistor 51.

a $ hen. ά, · .τ supplies a switching voltage 53. The switching voltage 53 is obtained in that the primary winding of the transformer 52 is connected to two terminals A and B, which are attached to one on the Tran *, formator 3 in the line generator 1 through

a damping resistor 54 bridged winding 55 are connected. Of course, the winding 55 of the transformer 3 can also be connected directly to the transistor 51.

The circuit arrangement according to Fig. 1 for Durrh-

performing the east-west raster correction can be simplified as follows to explain the mode of operation. A bridge circuit contains the Zcilcnablenkspulenhälften 18 and 19 and the windings

20 and 21, to which the capacitor 23, which is de-energized when the back equilibrium is set, is parallel is switched. At the windings 20 and 21 arrows are drawn which indicate the positive directions of the indicate deflection currents flowing through the coil halves 18 and 19. The opposite direction of the arrows means that equal deflection currents through the series connection of the bifilar windings 20 and

21 do not develop tension. The capacitor 23 can thus be viewed as a short circuit, so that actually a connection of the coil halves 18 and

19 is made directly to the relevant end of the winding 26 of the transformer 27. The circuit arrangement is fed by the linearity coil 16, the resistor 17 and the deflection coil sleeves 18 and 19 via the windings 6 and 7 of the transformer 3 in the line generator 1 and via the secondary winding 26 of the transformer 27.

The line generator 1 supplies a line frequency sawtooth lowering current with an almost constant amplitude. The positive direction of this current marked with / ,, is indicated by an arrow in the case of the voltage 15 indicated above the winding 6. The almost constant amplitude of the current i _d can be derived from the voltage 15, which has almost the same positive voltage value during each line run time T _11.

The primary winding 28 of the transform ¹¹ '^ 27 is! connected in series with the winding 29 of the transformer 3. In explaining the arrangement can

(ο

7 8

in the first instance the influence of the winding 29 is neglected. The winding 29 of the transformer 3 is neglected in series. The series circuit, which is connected in parallel with the winding 28 of the transformer 27 connected capacitor 30, is the let, in order to avoid that the current; _{rf is} transmitted from the voltage 50 occurring across the capacitor 49 winding 26 to the winding 28, since the transistor 51 is conductive during the line 5 across the winding 29, running time>, i. During the line transit time T ₁ , which is short in relation to the line transit time T 1 as a function of time, the same as the field transit time T _v , the voltage IS of the winding 6 remains. Above which the value of the voltage 50 is more or less con- winding 28 is under the effect of the star ». As a function of the more or less winding 2θ flowing current i _t an equal chip constant instantaneous value and from which essentially generated. From the inductive secondary loading of the Trans- indicated by the + and -signs it follows that the inductor 27 will flow through the winding 28 a linear, equal voltages through the windings variable current i ", which at the end of the 28 and 29 have opposite polarity and thus compensate for the line delay T _{n indicated by an arrow.} The line generator 1 can then achieve a certain maximum> 5 in the positive direction without any influence on the modulator with the value. The blocking of the transistor under 5i Zeilenablenkspulenhälften 18,19, the transformer, the effect of the switching voltage 53 during the 27th to the capacitor 30 and that a connected transistor exercise the lines with line frequency jerk term Λ T ₁₁ hai result, 51st The influence of the oscillation circuit is excited. This vibration through the winding 29 current flowing / ,, the circle has an inductance substantially through »o other windings of the transformer 3 is due to the parallel connection of the mutual inductances of the very large difference in the number of windings of the transformer 27 and parallel to each other - negligibly small.

lying weakly magnetically coupled row, the East-West Raslerkorrektur is determined the Kissenverzeichablenkspulenhälften 18 and 19, by means of the currency voltage is determined by the Zeilenablenkspulenhälften rend the capacitance by the capacitor 30 loading "5 1" 19 and the currents flowing i _AESS characterized is erstimmt. the leakage inductances are of the hold, in that a correction current i "vm the Ablenkverwendeten inductive components of the Vorrich- current / _rf subtracted. the parabolic vertung. uie relatively small inductance of the änderliche amplitude of the line frequency sawtooth linearity coil 16 and the stray capacitances correction current / "is neglected at the beginning and at the end of the. By means of the capacitor 30, the 30 partial image output T _{v can be} maximally and approximately in the period of the oscillating circuit (18, 19, 27, 30) in the middle of this time almost zero in the same way almost equal to twice the line return variable current i _dn can thereby be obtained \ T " to be made. At the end of the back of the line. That the deflection current i _d a correction current / "transit time 1T ₁₁ is thus added to the current i" after a half, which at the beginning and at the end of the ben period of a cosine change is close to / u 35 field delay time 7 \ almost zero and approximately in the certain maximum value in the negative sense of the middle of this time reaches the maximum value. If reached: another cycle can then occur. the circuit arrangement shown in FIG. B. a line frequency sawtooth current i "is generated, the connection point of the Trandessen serving as a switch amplitude during the field delay time T ₁ , 40 sistor 51 is exchanged for that of the capacitor 49 determined by the instantaneous value of the voltage 50. The capacitor 49 should then be selected. The result is a parabolic modulated, rend of a field runtime Γ, a positive voltage line frequency sawtooth current / „. its envelope lead, the course of which corresponds to that of the mirror image to the course of the voltage 50 during the partial image of the voltage 50 in relation to the reference time T _v given by oV. In the case of a transformer 27 45 nete ground potential.

with z. B. a gear ratio of 1: 1 is 7 to achieve the color correction mentioned

an equal current i " flows through the winding 26, the screen of a picture tube in a color television

whose positive direction indicated by an arrow playback device must be connected to the modulator in a

is. It turns out that the circuit arrangement of the line genes according to the invention is a partial

rator 1 supplied line deflection current i _d and the 50 more or less sawtooth

the transformer 27 supplied correction current / "shaped profile are fed. To this

have opposite directions, so that they are

Sensibly deliver a current i _d -? "". For the rator 2 mil two windings 56 and 57 are spared

the line deflection coil halves 18 and 19 flow. via the parallel connection of a potentiometer 58

current denoted by i _dr , whose positive direction 55 and a decoupling capacitor 59 for the partial

tune is indicated by an arrow. applies that frame rates are connected in series. The free

Ends of windings 56 and 57 are about two in

i _ilt = ' i (i _d - i _r ). Series connected capacitors 60 and 61 connected together. The connection point of the row

The result is. that through the line deflection coil 60 circuit of the capacitors 60 and 61. the line frequency sawtooth line frequency signals form a short circuit for halves 18 and 19, deflection current i _dl> flows, the amplitude of which starts at the tap of potentiometer 58 up to approximately the middle of a partial image _{transit time 7 ~ v} and increases in the form of a parabolic second via the series connection of a second Vick up to a maximum value. Development 62 of a transformer 63 and a resistor is determined by the almost constant amplitude of 65 level 64 at the grounded connection point of the current i _d , whereupon it again ended parabolic until the end of windings 24 and 25 of transformer 22 with the partial image transit time T _v. That with the capacitor 60 \ erbuiuleiK · takes. The end of the winding 56 is connected to the anode

9 10

Diode 65, the cathode of which at the free end of the voltage 70 has the same values. Which is connected during a Zei-winding 24. The free end of the winding 57 is then likewise the same over a corresponding length of time T _n flowing currents / ,, and /, _2. As a result, no current / i is induced in the winding diode 66 with the free end of the winding 25 compared to 20 and 21. During the blind. The transformer 63 has a primary winding. The second half of a partial image transit time T _v is the voltage 67 that is applied to the terminals A and Π of the voltage 70 higher than the voltage 69, so that the winding 55 attached in the trans-line generator 1 to the formalor 22 a current / _J2 / ,, a magnetic supply of a switching voltage «is connected. Generated at flow. This corresponds to: a current /, in the negative one end of the winding 62 is the direction above it. The result of this is that the line frequency holding voltage with 68 an- io line deflection coil halves 18 and 19 reinterprets a line. frequency sawtooth correction current is generated whose

The field generator 1 supplies to the more or less linear remote from the amplitude during the potentiometer 58 terminals of the con- first half of a sub-picture run-time T _v to zero off capacitors 60 and 61 field-frequency sawtooth decreases and again feed during the second half The voltages 69 and 70, which increase in the middle position of the ij, in which halves the directions of the Kor tap of the potentiometer 58 have almost the same correction current at the end of a line delay T ₁₁ amplitudes . At the beginning of a Teilbüdlauf- are opposite. For the color correction in each time T _v , the voltage 69 has a maximum value and the four quadrants of the display screen require the voltage 70 a minimum value, which values change the direction of the correction during a line delay T _n more or less ao current /, at Transition from one quadrant to remain constant. The positive value occurring to the other can easily be carried out by the circuit arrangement switching voltage 68 leads during a line run according to the invention, time T ₁₁ the diodes 65 and 66 in the conductive connection means of the bridge circuit and the counter and holds them therein . As a result, in set directions of the currents i _dß through the bifi- dependence on the instantaneous values of the span-as lar windings 20 and 21 it is ensured that voltages 69 and 70 through the windings 24 and 25 of the line generator 1 and the modulator (18, 19 27. of the essentially inductively loaded transformer 30, 51) for carrying out the east-west raster cot mators 22 linearly changing currents / _$ , and i _ti rectification does not affect the color correction modulator . The influence of the capacitor 23 is in the sen can. The color correction modulator has a line delay time T ₁₁ zero, since the bridge circuit, which is basically set to the equilibrium 30 from the line deflection coil halves 18, does not carry any voltage. 19, the capacitor 23, the transformer 22 and _{the directions of the currents / ,, and /, 2} through the opposite line frequency-controlled diodes 65 and 66 indicated by arrows. The color correction modulator contains the potentiometer

the z. B. bifilar wound turns 24 and 25 meters 58, to a difference in the level of the same only a current / ,, i, ₄ a magnetic 35 voltages in the voltages 69 and 70 set flux in the transformer 22 generate. By being able to. As a result, the point in time at which the windings 20 and 21 are connected in series in currents / ,, and / ,, are of equal size , shifted around do; consequently, an almost linearly variable current half the value of the field delay time T _v \ u

the. In this way, without influencing d =

/, - l / fl (/ ,, /, j) 40 bridge equilibrium of the line frequency correction

Current /, the point in time at which the amplitude Nut '

induced, where α is the gear ratio of the, are shifted. This setting option ·! Windings 20. 21 and 24, 25 of the transformer may be used to perform a not perfectly sy: -i 22 represents. The current /, through which the serial metric color correction is necessary, switching of the line deflection coil halves 18 and 19, 45 to the disturbing influence of the threshold value span so that the coil half 18 from a current i _dn - /, voltages and the non-linear part da and die Coil half 19 from a current / _rf " f /, current-voltage characteristic curve of the diodes 65 and 66 au. are flowed through. A resistor 64 is used to eliminate the switching effect

The negative pulse of the switching voltage 68 blocks, through which a current / _ss = / ,, ^: 'flows through the diodes 65 50 during the line retraction time I T _n. By means of the resistor 64, the current 1, and 66. The current 1, 1 of the moment is set in such a way that at the minimum amplitude value of the voltages 69 and 70, depending on the current 1, ₂ at the beginning of the field runtime T _{v has the} correct value. can then in an oscillation or the current / ,, at the end of the same the tension curve · ¹ : guneskreis. which essentially the windings 20 over the diode 66 or 65 is even higher than iii; · and "21 ties the transformer 22, the magnetic 55 threshold voltage. The line frequency current; an increase includes the capacitor 23, a free oscillation of the amplitude of the current /, by an equal perform by choosing the capacitance of the con- decrease in the amplitude of the current / _s, accompany; densators 23 is the period of the oscillation circuit is.. .

Π 8, 19, 20, 21, 23) almost equal to twice the Ό The mentioned color correction in a reproduction part r line return time 17 ",,. At the end of the line device, e.g. by means of the teH picture return time 17 ",, reaches the current /, after performing a deflection coil halves 42 and 43. Im half period of an eosine change the modulator must have the free ends for this purpose mentioned, certain value in the negative direction, the windings 20 and 21 of the transformer whereupon under the action of the switching voltage 69 65 to which the capacitor 23 is carved in parallel. a subsequent Zykiu approach can. not with the line deflection coil halves 18. 19 but

In the MÜle of a partial run-time T _v , the voltage 69 i <and which is consumed with the partial image tab coil halves 42, 43 and which are increasing. The connection point of the

liingcit 20 and 21 is attached to one end of the winding 41 connected. It is also possible to apply a correction current both through the lines (18, 19) and also lead through the Teilbildablenkspulenhälften 42, 43 / u, so that instead of a quasivierpoleeldes with two north or two south poles a quadruple field with four real poles is generated.

The transformer 22 with the four windings 20, 21, 24 and 25 can be through a bifilar coil with two series-connected windings are replaced. As a galvanic separation by the transformer 22 is obtained between the line deflection circuit and that coupled to the field generator 2 Color correction circle, this embodiment is to be preferred with regard to the effects of scattering.

It is found that on the screen of a display tube in a television display device by means of the line deflection coil 18, 19 and the in F ig. 1 arrangement shown both the normal Line deflection, the east-west raster correction of the pillow directory distortion as well as a color correction in color television can be realized simultaneously and without mutual interference Rönnen.

In the circuit arrangements according to FIG. 1, the line generator 1 feeds two deflection coil halves connected in parallel 13 and 19. In the embodiments of a circuit arrangement shown in FIG According to the invention, the line generator 1 feeds two deflection coil halves connected in series 18 'and 19'. The line next to the reference numbers indicates the fundamentally different connection method of the line deflection coil halves on. The components according to FIG. 1 are partially here, insofar as the connection method is not is fundamentally different, with the same reference numbers designated. Somewhat modified parts are given different reference numbers.

The series connection of the line deflection coil halves 18 'and 19' is at one end of each of the windings 6 and 7 of the transformer 3 in the line generator 1 connected. The other ends of the windings 6 and 7 are connected via a parallel circuit Coil 71 and a series connection of a capacitor 72, the linearity coil 16 and the capacitor 30 connected to one another, with which the winding 29 of the transformer 3 and a coil 73 are connected in parallel. The connection point of the capacitor 30 and the winding 29 is to earth connected. The coil 71 consists of two bifilar windings 74 and 75, whose connection point is about a parallel connection of the capacitor 23 and a winding 76 of a transformer 77 with the connection point the line deflection coil halves 18 'and 19' is connected.

The transformer 77 is provided with a primary winding, the two windings connected in series 78 and 79, those for carrying out the mentioned color correction on the display screen a line rate controlled field rate sawtooth voltage is fed. Performs the east-west raster correction of the pincushion distortion on the screen in a black and white or color television display device the capacitor 30 is a line frequency controlled, field frequency parabola voltage fed.

The circuit arrangement according to FIG. 2 for the east-west raster correction of the pincushion distortion is designed as follows: The field generator 2 supplies the field frequency parabolic voltage 50 to the capacitor 49 via the transistor 45, which is connected as an emitter follower. The terminal of the capacitor 49 carrying the voltage 50 is connected to the S cathode a diode AQ, the anode of which is connected to the junction of the capacitor 30 and the coil 73, and on the other hand connected to the emitter electrode of a pnp-type transistor 81, the collector electrode of which is connected to a tap of the coil 73. In order to achieve a switching voltage between the base and the emitter of the transistor 81, a winding 82 connected directly to the emitter electrode is fitted in the transformer 3. The winding direction of the winding 82 is opposite to that of the other windings of the transformer 3, which is indicated by the polarity of the voltage 83. This is not essential, but serves to simplify the illustration in FIG. 2. The other end of the winding 82 is connected to the base of the transistor 81 via the parallel connection of a capacitor 84 and the series connection of a capacitor 85 and a coil 86. A capacitor 87 and a damping resistor 88 are connected in parallel between the base and the emitter.

As described in the circuit arrangement according to FIG. 1, the line generator 1 supplies the line deflection coil halves 18 'and 19' with a line frequency sawtooth current i _d caused by the voltage 15 and having an almost constant amplitude. Since the inductance of the coil 71 is considerably higher than the impedance of the parallel-connected series connection of the coils 16 and 73, the winding 29 and the capacitors 30 and 72, the current i _{d flows} almost completely through this series connection. The current i _d calls via de "coil 73 produces a voltage whose polarity is f and inscribed. The magnetic coupling generates a voltage across the winding 29 of the transformer 3, the polarity of which is also indicated. By making the voltage across winding 29 equal to that across coil 73, these voltages cancel each other out due to the opposite phase. For the current / ,, the capacitor 30 is short-circuited as it were. As a result, the current i _d cannot influence a voltage across the capacitor 30.

The capacitor 72 is used for the so-called S correction, in which the current i _d does not change linearly during the line delay T _n , but rather in an S-shaped manner over time.

To carry out the east-west raster correction of the pincushion distortion, the voltage 50 is fed to the capacitor 30 via the electronic switch containing the diode 80 and the transistor 81 during the field delay T _v in each line delay T _n. To explain a cycle occurring during each line period, it is assumed before the beginning of a line delay time T _n , a voltage being present across the capacitor 30 which is equal to the sum of the instantaneous value of the voltage 50 and the voltage drop across the then current-carrying diode 80. The relatively small voltage drop across the diode 80 can be neglected compared to the voltage 50, which is more or less constant during the line delay T _1. The diode 80 is traversed by a current that decreases almost linearly to zero from the beginning of the line transit time T _n. In the middle

of the line delay T _n , the transistor 81 should become conductive and uniformly conduct a current flowing in the opposite direction. In order to eliminate the influence of the threshold voltage of the diode 80 on the uniform transfer, the transistor 81 is connected to the tap of the coil 73. In order to obtain the correct moment for current transfer, the switching voltage 83 is fed to the base and the emitter of the transistor 81 via the network (84 to 88). The coordinated network deforms the switching voltage 83 in such a way that almost in the middle of the line delay time T ₁₁ the base of the transistor 81 becomes negative with respect to the emitter. On. At the end of the line delay time T _n, the pulse of the switching voltage 83 blocks the transistor 81. The current inductances of the tightly coupled windings fi. 7 and 29 of the transformer 3 are for the time being neglected, so that an oscillating circuit is excited which, parallel to the capacitor 30, contains the coil 73 on the one hand and the series connection of the coil 16, the capacitor 72 and the row numbered coil halves 18 'and 19' on the other. The inductance of the resonant circuit is largely determined by the relatively low value of the coil 73. By means of the capacitor 30, the period of the resonance frequency is made almost equal to twice the rate return time I T _n . As shown in Fig. 1 is already described, as a result, at the end of the line return time. I T _{n is} the state which is the initial state at the beginning of the running time T _n .

The circuit arrangement according to FIG. 2 contains a modulator which, if neglecting the incariity coil 16 and the V correction capacitor 73, essentially contains: the line frequency controlled. electronic switch with the diode 80 and the transistor 81, the capacitor 30 and the coil 73 connected in parallel therewith and the series connection of the Zcilenablcnkspulenhälftcn 18 'and 19'. During the partial run time Ty , the parabolically variable voltage 50 is fed to the capacitor 30 at each line cycle time T _11. A comparison of the polarity of the voltage applied to the capacitor 30 with that of the voltage 15 shows that these are opposite to one another. The subtraction that then takes place shows that the signal coil halves 8 'and 19' are not from the current / ,, with constant amplitude but from a line-free | Ucii7 saw current / ,,,, with a partial image frequency. parabolically variable amplitude are flowed through. As in the case of FIG. I, an addition could of course also be carried out.

Is shows that the capacitor 49 is charged via the electronic switch with the diode 80 and the transistor 81 during the first half of the cycle time T _n , while it is discharged in the second half. In this way there is a saving. so that less power is withdrawn from the partial image generator 2 for the east wetting razor correction. Of course, the circuit arrangement according to FIG. be given away with a similar savings circle in which t. B. a diode with the opposite current direction is connected in parallel with transistor 51.

The circuit arrangement of Fig. 2 5ft for the l'arhkorreklur isi to that shown in Fig. 1 fashion with the windings and 57 of the transformer 31 in the Teilbildt> encraior 2, provided the order of parallel capacitors 60 and 61 and the diodes 65 and 66. For the sake of simplicity, the windings 56 and 57 are directly connected to one another; also the potentiometer 58 of FIG. 1 and the capacitor 59 can be attached. The diodes 65 and 66 are connected to the free ends of the series-connected, earthed windings 78 and 79 of the transformer 77. The series connection of the emitter-collector path of a transistor 89, a winding 90 of a transformer 91, is attached between the grounding point and the connection point of the capacitors 60 and 61. The emitter of the transistor 89 is connected to the base via a winding 92 of a transformer 93. A winding 94 of the transformer 91 and a winding 95 of the transformer 93 are oppositely connected to the terminals A and B , which form the output terminals of the winding 55 of the transformer 3. Of course, the windings 90 and 92 can also be attached directly to the transformer 3. The windings 90 and d 92 carry the voltages 96 and 97, which are given at one end of the winding as a function of time. Under the action of voltages 96 and 97 and those induced in windings 56 and 57. Field frequency saw number voltages appear across the capacitors 60 and 61, the voltages 98 and 99 indicated at a terminal of the same.

The level of the ground potential oV in the voltages 98 and 99 shows that the diodes 65 and 66 can each conduct on their own only during half a period of time T _x. The voltage 98 can keep the diode 65 conductive during the first half of the field delay time Ty. Under the effect of the switching voltage 97, as a result of the negative voltage occurring at the base of the transistor 89 during each line run time T _n , this transistor becomes conductive, which also applies to the diode 65. Depending on the instantaneous value of the partial image frequency voltage change 98, a current i _sv flows through the winding 78 and induces a corresponding current 2 /, indicated by an arrow in the secondary winding 76 of the transformer 77. As a result, a current flows through the series connection of the Zcilenablcnkspulcnhälftc 18 ', the winding 6 and the winding 74 or 19'. 7 and 75. There is no voltage across the bilateral windings 74 and 75 of the coil 71

5η due to the opposite directions of the currents / «. so that for current 1, the coil can be viewed as a short circuit. This also applies to the magnetically tightly coupled windings 6 and 7 of the transformer 3. Accordingly, the transformer 77 feeds a parallel connection of the magnetically weakly coupled toothed coil halves 18 'and 19'.

At the beginning of the line return time .tT _n, the transistor 89 blocks under the effect of the switching voltage

97. and through the diode 65 no more current can flow. As a result, an oscillating circuit is excited, which essentially comprises the capacitor 23. the parallel winding 76 with relatively low inductance and the Zcilcnablenk- bobbin tubes 18 'and W revealed. By means of the condenser 23, the period of the resonance frequency of the oscillating circuit is set to almost twice the cilcnrik-kliiufzcil ST ₁₁ . As before-

as described above, a line frequency sawtooth current; _{s is} generated, the amplitude during the first half of the field delay time 7 \ · depends on the instantaneous value of the voltage 98. The directions of the currents given for the line deflection coil halves! 8 'and 19' indicate that, during the color correction, the coil halves 18 'are traversed by the current i _d "- i _s and the coil half 19' by the current I _11n + i _s .

During the second half of the field runtime T ₁ . the diode 66 can become conductive under the effect of the voltage 99. The current flowing through the winding 79 / _s . induces a current in the winding 76, the positive direction of which is opposite to the indicated arrow and thus represents the required negative direction through the winding 76.

In order to achieve a uniform current transfer from the blocking diode 65 to the diode 66 which becomes conductive, the winding 90 is connected in series with the transistor 89. During a line run time T ₁₁ is. apart from the voltage drop across the transistor 89. the collector electrode of the same at ground potential. The end of the winding 90 connected to the capacitors 60 and 61 carries a constant, positive DC voltage under the effect of the induced voltage 96 of the line run time T _n , which is expressed in the field frequency range 98 and 99 in the form of an asymmetry with respect to earth potential . The low value of the direct voltage component of voltages 98 and 99 corresponding to the threshold voltage of diodes 65 and 66 gives! the uniform current transition in the middle of the partial running time 7 \.

The circuit arrangement for the color correction according to FIG. 2 requires less power than the one after. I. Since the diodes 65 and 66 can only conduct on their own for a half instead of a full field transit time T _v , the Olim losses in the arrangement are lower. As a result, to switch transistor 89 of FIG. 2, less power is withdrawn from the line inverter 1 than in the arrangement according to FIG.

Hs shows that by the in the F i g. I and 2 "! Postage arrangements sent to you are the normal Line deflection, the Osl-Wcst-Rasterkorrcktur Kiss drawing and color correction itself

{; lcich / citig and perform independently of each other iisseri. According to FIG. 2, the windings 6 and 7 form Oes transformer 3 part of a pressures that Furthermore the coil 71, the Zeilcnablcnkspiilenhälftcn 18 'and 19', the winding 76 and the transistor 23 contains. A bridge balance, once fixed, should be achieved by other settings in the television display device no longer be disturbed. The F. decoupling effect of the coil 71 ensures that in a Parallel connection thus without disturbance the necessary / terminated Corrections such as the S correction using z. 0. a variable capacitor 72 and the Correction of the linearity can be carried out by means of the capstan 16 are.

F. it will make sense. "IflH at in series geschalv'.en" s TeilbildiMienkspulenhälflcn 42 and 43 also those in Fit! 2 illustrated arrangement for the color correction can be used. Ms will shine aiilk-rdem, that any combination of the in Figs. 1 and 2 illustrated embodiment of a circuit arrangement is possible according to the invention.

Claims (13)

Patent claims: 1. Circuit arrangement for generating a line-frequency sawtooth current with field frequencies Changes in amplitude in a television display device, soft arrangement with a line and a field deflection current generator for supplying a line and field frequency, respectively Sawtooth current with almost constant amplitude to a Z, ilen- or partial image deflection coil and with a modulator controlled by the field number steering current generator for Achieving the field-frequency amplitude changes of the line-frequency sawtooth current c * provided is. characterized in that the modulator is one with the line frequency switching, electronic switch (65. 66) contains during the Hiniaufzeit of the Line deflection current generator (1) to the line deflection coil (18, 19 or 18 '. 19') supplied sawtooth current to the Teilbildablenkstromgencrator (2). which supplies a voltage that changes with the field frequency, with an oscillating circuit which connects in parallel a capacitor (23 or 30) and a line (18, 19, 18 ', 19') or Teilbildcnkspule contains extensive inductance, whereby the period of the resonance frequency of the oscillating circuit is almost twice the flyback time of the Line frequency Sägczahnablenkstromes is. 2. Circuit arrangement according to claim 1 for use in a color television playback device. characterized in that the inductance of the resonant circuit with at least four inductances (18, 19, 20, 21 or 18 ', 19'. 6.7,71), two of which are provided by the line (18. 19 or 18 ', 19') or Teilbildablcnksnulen determined will. 3. Circuit arrangement according to claim 1 or 2, characterized in that the two Coil halves of the line (18, 19) or Tcilbildablcnkspule in a bridge circuit in parallel are fed by the line (1) or Tcilbildablenkstromgenerator, the / wci other inductances of the bridge circuit in the form of two bifilar windings (20.21) are designed to the relevant deflection current generator (1) and the modulator (18. 19. 22, 23. 65, 66) to decouple. 4. Circuit arrangement according to claim 3, characterized in that the series connection of the mentioned bifilar windings (20,21) forms the secondary winding of a transformer (22), the primary winding (24, 25) of which via the electronic switch (65, 66) with the Tcilbildablcnkstromgcncrator (2) connected isl. which supplies a more or less sawtooth-shaped, line-image-like voltage (69.7 »). 5. Circuit arrangement according to claim I or 2, characterized in that the two dull Line (IH. 19) b / w Spool Sleeves. Sub-image deflection game in avr llrüi-kenscliiilliiitg in KeiIic um dem / eilen- (I) or IVilhildabli-iiKslioin generator are fed, while the other two inductances of the bridge circuit are off one winding (6 or 7) each of one housed in the line (1) or partial image deflection current generator Transformer (3) and a winding (74 or 75) of a coil (71) are assembled, wherein the two coil windings (74, 75) are bifilar wound around the respective deflection current generator (1) and the modulator (18 ', 19', 23, 77, 65, 66) to be decoupled. 6. Circuit arrangement according to claim 5, characterized in that in parallel with the capacitor (23) a secondary winding (76) of a transformer (77) is provided in the bridge circuit is, whose primary winding (78, 79) via the electronic switch (65, 66) with the Teilbildablen.'istromgenerator (2) is connected. the one more or less sawtooth-shaped field frequency Voltage (98, 99) supplies. 7. Circuit arrangement according to claim 4 ao or 6, characterized in that the Teilbiidablenkstromgenerator (2), which is a more or less sawtooth-shaped field-frequency voltage supplies, is provided with a transformer (31) on which two windings (56, 57) are mounted via the parallel connection of a potentiometer (58) and a capacitor (59) are connected in series, where the free ends of the windings (56, 57) and the tap of the Potentiometers (58) via electronic switches (65, 66) to the free ends and one Center tap of the primary winding (24, 25) of the transformer (22) mentioned in the bridge circuit are connected. S. circuit arrangement according to claim 1 for 3. ^r > performing the east-wcst raster correction of the pincushion distortion on the screen of a display tube, characterized in that in series with the circuit of the line deflection current generator (1) and the line deflection coil (18, 19 or 18 ', 19') an inductance (27 or 73) forming part of the inductance of the resonant circuit is provided. 9. Circuit arrangement according to claim 8, characterized in that with the mentioned, of the line deflection current through which inductance (27 or 73) flows on a transformer (3) of the line deflection current generator (1) attached winding (29) connected in series is, which series circuit is connected in parallel with the mentioned capacitor (30), wherein the voltage generated across the winding (29) of the series circuit is the voltage generated by the line deflection current with constant amplitude induced voltage decrease of the inductance (27 or 73) same but opposite to the line deflection current generator (l) and to decouple the modulator (18, 19, 27, 30, 51 or 18 ', 19', 30, 73, 80, 81). K). Circuit arrangement according to Claim 8 or 9, characterized in that the capacitor (30) of the oscillation circuit and the electronic switch (51 or 80, 81) in series the terminals of a capacitor (49) are connected, one terminal of which is connected to the Partial deflection current generator (2) is connected, which has a more or less parabolic partial image frequency Voltage (50) supplies. 11. Circuit arrangement according to claim 3 and one of claims 8, 9 and 10, characterized in that said inductance a first oscillating circuit forming bridge circuit (18, 19, 20, 21), which the two Contains coil halves (18, 19) of the line deflection coil in a series connection with the aforementioned Inductance ^ 27) the inductance of a second Oscillating circuit is connected to the line deflection generator (1). 12. Circuit arrangement according to claim 5 and one of claims 8, 9 and 10, characterized characterized in that the series connection of the two bifilar windings (74, 75) of the coil (91) in the mentioned bridge circuit (18 ', 19 ', 6, 7, 71), which contains the two coil halves (18', 19 ') of the line deflection coil, in parallel with one relatively low impedance (16, 29, 72, 73) is connected, which the mentioned inductance (73) which forms part of the inductance of a second oscillating circuit. 13. Circuit arrangement according to claim 12, characterized in that said low Impedance (16, 29, 72, 73) a capacitor (72) for performing the 5-correction in series with the mentioned inductance (73) of the second oscillation circuit. 1 sheet of drawings