DE976252C - Circuit arrangement for the magnetic deflection of a cathode ray - Google Patents

Description

(WiGBl. P. 175)

ISSUED JUNE 12, 1963

R 1 572 VIII α / 2i a *

(No. 90 612)

The invention relates to a circuit arrangement for the magnetic deflection of a cathode ray with a deflection coil connected directly to the Anode is coupled to a deflection tube.

In the construction of circuit arrangements for the magnetic deflection of a cathode ray a cathode ray tube are a whole series of requirements to be considered. the Circuit arrangement should of course be as simple and inexpensive as possible, to the manufacturing and Keep maintenance costs low. In some areas of application, on the other hand, the Forde ^ Proceed to all other requirements according to the lowest possible weight and space requirements. The efficiency of the circuit arrangement, i.e. H. those with a certain DC input power achievable distraction also plays an important role. With so-called multi-standard devices It is also required that the deflection circuits operate at different frequencies operate or at least easily convertible

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are cash. In practically all cases, energy recovery should be used, i. h., it should the Energy stored in the form of a magnetic field during part of the deflection period can be made usable. With the picture tubes with flat The fluorescent screen is also a certain deviation from an exactly time-linear course of the Deflection current desired in order to compensate for the so-called ίο tangent error.

A known horizontal deflection stage (Proc. I.R.E. 1947, pp. 813 to 821, in particular Fig. 11, S..820) contains an end tube, the anode of which is connected to a primary winding of a combined deflection and high voltage transformer is connected. The transformer works re the high voltage generation as an autotransformer, but it contains three separate secondary windings, for feeding the heating of a high-voltage rectifier tube, for coupling of line deflection coils or to couple a switch or damping diode. Between the end of the primary winding of the transformer facing away from the anode and the positive pole an anode voltage source for the deflection tube, a capacitor is connected to the the cathode of the switch diode connected to the energy recovery capacitor via a fixed Inductance is charged with such a polarity that the voltage across it increases added to the voltage supplied by the anode voltage source. The two capacitors and the inductance form a low-pass filter, which is dimensioned so that the at the cathode of the switch diode occurring pulses are delayed by approximately one line duration. The one through the low pass delayed AC voltage component of those occurring on the energy recovery capacitor Voltage is used in the known circuit arrangement to correct deflection distortions that are caused by the attenuation circuit. the The anode of the switch diode is connected to the positive pole of the anode voltage source via one of the secondary windings tied together.

This circuit arrangement has the fundamental disadvantages of all those containing a transformer Deflection stages, namely that the one to be dimensioned for the relatively low line frequency Deflection transformer is an expensive, large and heavy component that causes distortion and losses caused. In the above-mentioned known circuit, it has a particularly complicated structure. In the known circuit arrangement, there are also no provisions for compensation of the tangent error provided.

It is still a self-oscillating transformer flip-flop known (Swiss patent specification 223 180; French patent specification 880294, especially Fig. 5). The anode alternating voltage is via a transformer, whose Primary winding in the anode circuit and the secondary winding in the grid circuit is on the grid of the tilting tube is fed back so that self-excitation occurs. The deflection coils can be connected to a special secondary winding of the transformer, but it is also known to couple the deflection coils to the winding of the feedback transformer located in the anode circuit of the tilting tube. A linearizing diode connected in series with an energy recovery capacitor is attached to the deflection coils connected in parallel, the positive pole of the anode voltage source is at the connection point between the energy recovery capacitor and the anode of the linearizing diode connected. Since the deflection coils also in this circuit arrangement via a transformer are coupled, it has essentially the same disadvantages of the known as the first mentioned Circuit arrangement, even if the deflection transformer is somewhat simpler in structure is that it works as an autotransformer with regard to the coupling of the deflection coils. Precautions to compensate for the tangent error and to generate a high voltage for supply the picture tube are not provided in this circuit arrangement.

There is also a circuit for generating sawtooth currents known (British patent 482 370) which contains an amplifier tube controlled by a blocking oscillator. Between the The anode of the amplifier tube and the positive pole of the operating voltage source is a primary winding of a deflection transformer, whose secondary winding is connected to a deflection coil is. In parallel with the primary winding there is a series circuit made up of a damping diode and a i? C combination.

In a modification of this circuit arrangement, the series circuit consists of the damper diode and i? C combination between the end of the primary winding facing away from the anode of the amplifier tube of the deflection transformer and a tap of this transformer connected, and the positive The pole of the anode voltage source is at the connection point between the anode of the damping diode and connected to the ÄC combination. The capacitor of the i? C combination works as a Energy recovery condenser. This circuit arrangement also contains a transformer.

Furthermore, there is an arrangement for the electromagnetic deflection of the cathode ray in cathode ray tubes known (Swiss patent 221476) that no deflection transformer contains. The deflection coils are DC-free directly between the anode and cathode of the deflection tube switched. This circuit arrangement is simple and inexpensive and has a small space and size Weight requirement. The adaptation of the tube to the deflection coils can be solved satisfactorily. These However, known circuit arrangement has the usually prohibitive disadvantage that no energy recovery is provided. In addition, it does not contain any measures to dampen natural oscillations of the deflection coils and to avoid the tangent error to correct.

It's also a power sawtooth generator

been proposed (German Patent 757 933), in which the tangent error by means of a capacitor connected in series with the deflection coil is compensated.

In summary, it can be said that the known Circuit arrangements for the electro-magnetic deflection of a cathode ray either contain a deflection transformer or no ίο energy recovery and no high voltage generation enable.

The invention therefore has the aim to provide a circuit arrangement of this type that has a particularly small space and weight requirements

! 5, easy and cheap to manufacture and Maintenance is and is still not based on energy recovery with good efficiency and the generation of a high voltage for operating the cathode ray tube is dispensed with. aside from that the tangent error should be compensated at the same time.

A circuit arrangement for the magnetic deflection of a cathode ray with a deflection coil, also with one of an operating voltage

* 5 source-fed deflector tube that is at rest is blocked by a preload and at least * - at least in the second half of the path of the cathode ray an approximately linear time increasing Supplies electricity, furthermore with a high-voltage impulse transformer, whose primary winding is in the anode circuit of the deflection tube, with a switch diode and a storage capacitor for energy recovery is characterized according to the invention in that the primary winding of the pulse transformer, the deflection coil coupled without a deflection transformer and the Storage capacitor in series in the anode circuit of the deflection tube; that the switch diode in parallel to that part of the series circuit containing the storage capacitor and the deflection coil and that between the operating voltage source and the deflection tube an adjustable inductance in Series with the switch diode is connected, the one with the storage capacitor and another capacitor forms a filter member.

The invention will now be explained in more detail with reference to the drawings. Thereby means

Fig. Ι a circuit diagram of an embodiment of the invention applied to the horizontal deflection stage a television receiver,

Fig. 2 is a simplified circuit diagram of a television receiver having a deflection circuit according to a second embodiment of the invention includes and

3 shows diagrams for explaining the mode of operation of the invention.

The circuit arrangement shown in FIG includes a sawtooth generator which provides an output voltage 14 of the form shown.

To synchronize this sawtooth-shaped voltage, terminal 16 can be used for synchronization pulses are fed. The sawtooth voltage 14 is fed to the control grid 18 of an amplifier tube 20, which is connected as a cathode amplifier. The anode 22 of the tube 20 is over a resistor 24 is connected to the positive terminal 26 of an operating voltage source. the Anode 22 is in terms of alternating voltage via a capacitor 28 grounded. Between the cathode 30 of the cathode amplifier tube and a negative one Terminal 32 is a cathode resistor 34, the cathode-side end of which is galvanically connected to a control grid 36 of a deflection tube 38 is connected. Since the resistance value of the cathode resistor 34 the tube 20 is relatively small, voltages of large amplitudes can be fed to the control grid 36 without fear of distortion from grid current. The cathode 42 of the Deflection tube 38 is connected to ground via a cathode combination 40, 44. A screen grid 46 is to a positive terminal 48 via a resistor 50 and to the via a capacitor 52 Cathode 42 connected.

In order to achieve the desired anode voltage increase through energy recovery by means of the deflection coils 54, an upper terminal 58 of the coil is connected to the anode 60 via a capacitor 62 used to increase the anode voltage, which in turn is connected to a primary winding 64 of an autotransformer 66 to increase the voltage of the pulses that are in the return periods of a deflection coil are connected. A lower terminal 68 of the deflection coils is connected to a positive terminal 70 of an anode voltage source. A damping diode 72 is connected in parallel to the deflection coils 54 via a capacitor 74. In addition, the diode 72 is connected to the left side of the capacitor 62 via a choke coil j6. The choke coil 76 is used to adjust the linearity of the deflection. The high voltage for an accelerating oil electrode 78 of a picture tube 56 is generated by the pulse transformer 66. The deflection current for the deflection coils 54 flows through the primary winding of this transformer 66, so that positive high-voltage pulses occur in a secondary winding 80 during the flyback. These high-voltage pulses are rectified by a rectifier 82, so that a high DC voltage no is produced at a capacitor 84 and is fed to the acceleration anode 78 via a filter resistor 86. A secondary winding 88 of the pulse transformer 66 feeds a filament 90 of the rectifier tube 82.

The mode of operation of the circuit arrangement described can be explained most easily with the aid of the curves in FIG. The sawtooth-shaped current through the deflection coils 54 consists of two parts, namely a first part, which comes from the anode current i _{p of} the deflection tube 38 (curve 3 a) and a second part, which consists of a current i _d and through which in the deflection coil stored magnetic energy is generated and attenuated by the attenuation tube 72. It is known that the deflection tube 38 is so strongly negatively biased in such circuit arrangements that

only the upper part of the controlling sawtooth voltage 14 on the grid of the tube can produce an anodic current in the tube. Under normal operating conditions the anode current 3 flows only during the period of time T _"4, that is, while a little more than half the Strahlhinlaufes. Dental The whole Sä or deflection period is denoted by Γ. In Fig. A is at the end of period of time T _1, that is at the point in time at which the sawtooth 14 has its positive maximum, the tube 38 is blocked, since at this point the control voltage 14 quickly becomes negative After a half oscillation, the terminal 58 of the coil 54 becomes negative with respect to the lower terminal 68. The diode 72 then begins to conduct and represents a damping for the magnetic energy of the coil, ie it allows a current in the direction of part i _ä (Fig. 1). This current shown in Fig. 3b has the opposite direction as the current shown by the curve in Fig. 3a, and the currents i $, i _p together result in a virtually linear sawtooth current extending over the entire time span T _1. The voltage on the coil terminals is practically equal to L (di / dt) .

Since the cathode 72 of the switch diode 72 is at the positive potential of the terminal 70 while it is conducting, the capacitors 72, 74 connected via the coil 76 are practically charged to the voltage L (di / dt) , so that the loop voltage in the damping circuit is necessarily Becomes zero. As can be seen from the direction of the current i ^ , the capacitors 62, 74 charge with such a polarity that the increased anode voltage actually taking effect at the deflection tube 38 causes the current to begin shortly before the end of the time period T _s.

The positive voltage on the capacitors 62, 74 thus results from part of the magnetic energy that was present in the deflection coil at the end of the time period T ₁ . As mentioned, the current flow through the damping diode y2 prevents the terminal 58 of the deflection coil from falling appreciably below the potential of the terminal 70. The anode voltage increase which is brought about by storage in the capacitors 62, 74 can be reproduced by the dashed line 94 in FIG. 3 d. This line 94 is simply the AC axis of the coil voltage e _y , which, as stated, cannot drop significantly below the + B potential at terminal 70. The average voltage increase in the circuit is thus represented by the voltage E _b , that is to say by the dashed line in FIG. 3 d. According to this description, the current saw tooth in the coil 54 would have to run practically linearly if the inductance 76 in FIG. 1 were not present. In the case of television picture tubes with a relatively flat screen, however, this sawtooth curve is generally deliberately somewhat distorted in order to compensate for the effect of the flat luminescent screen, ie the so-called tangent error. The form of the distortion required for this is shown in FIG. 3 e. It can be seen that the coil current should not run strictly linearly over time, but should rise somewhat more flatly towards the end of the trace time than the precisely linear time curve shown in dashed lines. This rounding off of the sawtooth curve results in a reduction in the speed of the light spot near the end of the line, so that the tangent error is compensated.

The mode of operation of the coil 76, which serves to compensate for the tangent error, can best be understood with reference to curves 3 g and 3 h. 3g shows the voltage across the capacitor 62 which is generated by the sawtooth current charging it, and FIG. 3h shows the voltage occurring across the capacitor 74 which is generated by the fraction of the sawtooth current charging this capacitor. By suitable selection of the capacitance values of the capacitors 62, 74 in combination with the dimensioning of the coil 76 , the size of the two voltages, in FIGS. 3 g, 3 h, can be regulated. Since these voltages are actually in series with the anode-cathode path of the deflection tube 38 and also with the damping diode, they contribute to influencing the curve shape of the coil current. The resulting voltage applied to the deflection coil 54 will thus have approximately the curve shown in FIG. 3 f, which corresponds approximately to the coil current desired according to FIG. 3 e.

By adjusting the inductance 76, the size and phase of the AC voltage to the Capacitors 62, 74 can be changed relative to one another, so that the linearity of the deflection can be adjusted very largely.

Fig. 2 shows a modification of the inventive concept also applied to a television receiver. The receiver contains a receiving part 100 which, in the usual manner, contains a high-frequency amplifier, an oscillator, a mixer, an intermediate frequency amplifier, a video demodulator and a video amplifier. The output voltages of the video amplifier are applied to the grid of the picture tube 56, which, as in FIG. 1, is only shown schematically. The receiver also contains an amplitude filter 104 for separating the synchronization pulses, at the output of which a line deflection generator 106 and an image deflection generator 108 are connected. The latter has output terminals XX for connection to an image deflection coil 110. The line deflection generator 106 corresponds to the line deflection generator 10 in FIG. Otherwise, the same reference numerals have the same meaning in FIGS. 1 and 2. A voltage source 111 supplies the anode voltage required for the various stages. In televisions you often need

If the circuits were to have a higher supply voltage than they would normally from the anode voltage source in for the remaining consumers. For example, in FIG. 2, for the Image deflection generator IO8 must have a higher anode voltage in order to achieve a sufficient raster deflection amplitude to reach. In Fig. Ι the terminal no of the capacitor 62 provides an increased positive voltage through energy recovery as described so far. However occurs terminal 110 also has a fairly high positive pulse during the line return, as shown in FIG. 3 d shows. In order to apply this voltage to the terminal 110 of the image deflection stage, it would therefore be necessary to be to filter this voltage, what an additional filter coil and filter capacitance or a requires something cheaper i? c filter. .RC filters are relatively inexpensive, the one introduced by them However, resistance prohibits their use for feeding the image deflection stage.

In the circuit arrangement shown in FIG. 2, the anode voltage is increased by energy recovery as in FIG. 1, but the circuit arrangement is modified so that the increased anode voltage appears at the lower end of the deflection coil 54 and therefore does not contain the high positive flyback pulse. This is evident since in FIG. 2 the primary winding 64 of the pulse transformer 66 is directly connected to the terminal 58 of the deflection coil 54, while the; components 74, 62 ', 76' corresponding to capacitors 74, 62 and choke coil 76 are at the other end of the deflection coil. The normal anode voltage for operation of the deflection circuit is at terminal 112 of choke 76 ', while the increased voltage appears at terminal 114. Since a parabolic voltage, as shown in FIGS. 3 g and 3 h, appears on the capacitors 62 ', 74', between which the choke coil 76 'which can be created is located, the linearity can be changed in the same way as in Fig. i. The voltage at terminal 114 no longer contains the high return pulses, but still contains a certain amount of alternating current, so that it will be useful to filter it a little, e.g. B. by an IC filter 116, 117, which can have a low resistance. The voltage appearing across the capacitor 117 is practically equal to the increased voltage E _b in FIG. 3 d; it can be fed directly to the image deflection stage 108, as is shown in FIG.

In the circuit arrangements shown in FIGS it is important for influencing the linearity of the beam deflection that in the In the middle of the trace time there is an increased anode voltage and that therefore L (di / di) there has greater value. This in turn allows a greater overall deflection of good linearity. Since the The deflection circuit does not contain any ohmic resistors, the overall efficiency is also good the circuit arrangement.

In the following, the processes are to be considered in more detail, which are in the described Play circuit arrangements for energy recovery and anode voltage increase. In particular, the influences of the anode capacitance 39 of the deflection tube 38 and the Stray capacitances 55, 57 are considered. Through the series resonance circuit, that through the capacities 55,57 and the primary winding 64 of the pulse transformer 66 is formed, furthermore by the Anode capacitance 39 of the tube 38 and the capacitor used to increase the anode voltage 62 ', which is connected to ground via the anode voltage source 111, becomes during the beam return some of the energy stored in the primary winding 64 of the pulse transformer 66 the capacitors 62 ', 74' are transmitted. This is because the deflection tube 38 is at the start of the retrace time is blocked and the magnetic energy of the primary winding 64 in the aforementioned series resonant circuit starts an oscillation. The frequency of this oscillation depends on the winding capacitance 65 of the primary winding 64 and the stray capacitances of the circuit to earth. When the frequency of the series resonance circuit is set correctly to the resonance frequency of the deflection coils is, this free oscillation can run sufficiently far to the terminal voltage of the stray capacitance 57 to be added. This happens at a point in time when the terminal voltage of the coil 54 would otherwise be considerably lower. As a result, of course, the damping diode 72 accordingly more energy for the voltage increase at the capacitors 62 ', 74' for provided.

In practice, optimal conditions result when the resonance frequency of the series circuit, in which the inductance of the primary winding 64 of the transformer is approximately one and a half times ioo is the resonance frequency of the deflection coils. The changes with other frequency ratios energy recovered corresponding to the primary winding of the pulse transformer. Since the Initially counteract the transformer oscillation and the deflection coil oscillation, it will however, it may generally be desirable to set the natural frequency of the transformer higher than that of the deflection coils.

The energy recovered from the primary winding of the pulse transformer is available during the first half of the beam trail available, d. h, with ordinary television receivers during the left half of the picture. The linearity in the left half of the picture therefore depends considerably on the Choice of inductance of the primary winding of the pulse transformer in conjunction with the whole Stray capacitance of the circuit and the anode capacitance 39 as well as the stray capacitance 65 the primary winding of the pulse transformer. It can therefore sometimes be useful to use the Anode capacitance 39 to connect a lumped capacitance in parallel to the frequency of the primary winding suitable to influence. Furthermore, you can sometimes the stray capacitance 57 by a add fixed capacity parallel to it, there

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the energy stored in the primary winding of the pulse transformer in the form of an oscillation voltage at this capacity appears and the energy recovery and the linearity of the left half of the picture can be improved by this tension.

Generally speaking, the energy recovered from the pulse transformer represents a partial Compensation for the losses in the deflection coils 54. Since the primary inductance den Is the decisive parameter, it is evident that the transformer 66 should be replaced by a suitable fixed inductance can be replaced if one does not provide the voltage for the second anode the picture tube wants to gain from the sawtooth returns. If the series inductance is completely absent, the deflection amplitude often becomes too small for practical purposes.

In Fig. Ι serving for linearization inductance 76 also acts as a magnetic energy store, which, when the deflection tube 38 is blocked, generates a current of a particular waveform in the series circuit generated, which is formed by the inductance 76 and the capacitors 62, 74. Since the Voltage occurring in coil 76 forms a variable alternating current bias for diode 72, cannot be achieved by influencing the phase of this voltage appropriately and by choosing its frequency affect only the deflection linearity, but also the degree of energy recovery.

The deflection circuits according to the invention contain practically two coupled resonance circuits, one through the deflection coils 54 and the other through the primary winding 64, respectively Inclusion of the associated parallel capacitance is formed. The one used for linearization Coil 76 can be viewed as partially lying in both circles, depending on the ratio of the Capacitors 62, 74 depends. A closer inspection shows that the value of the capacitance is 39 in greatly influenced the coupling coefficient between the two circles. The capacity is 39 thus significantly involved in the energy recovery from the pulse transformer by means of the diode 72, and it has already been pointed out that it may be appropriate to increase the capacity 39 to be supplemented by a concentrated condenser.

Claims (3)

PATENT CLAIMS: ι. Circuit arrangement for magnetic deflection a cathode ray with a deflection coil, further with one of an operating voltage source fed deflection tube, which is blocked by a bias voltage in the rest state and at least in the second half of the outward run of the cathode ray supplies an approximately linearly increasing current, furthermore with a High-voltage impulse transformer, the primary winding of which is in the anode circuit of the deflection tube with a switch diode and a storage capacitor for energy recovery, characterized in that the primary winding (64) of the pulse transformer (66), the deflection coil (54) coupled without a deflection transformer and the storage capacitor (74) lie in series in the anode circle of the deflection tube (38); that the switch diode (72) in parallel with that part of the series circuit containing the storage capacitor (74) and the deflection coil (54) and that between the operating voltage source and the deflection tube (38) a adjustable inductance (76) in series with the switch diode (72) connected to the Storage capacitor (74) and a further capacitor (62) form a filter element. 2. Circuit arrangement according to claim 1, characterized in that the circuit parameters are dimensioned so that the natural frequency of the primary winding of the pulse transformer containing series circuit about one and a half times the natural frequency of the deflection coil is. 3. Modification of a circuit arrangement according to claim 1 or 2, characterized in that that the pulse transformer is replaced by a fixed inductance. Considered publications:
Swiss patent specification No. 221 476,
180; British Patent No. 482,370;
Proc. IRE, 1947, pp. 813 to 821. Legacy Patents Considered:
German patent specifications No. 757 933, 929318. 1 sheet of drawings © 309 605/7 6.