DE1512413C - Vertical deflection circuit for a television receiver, stabilized against amplitude and mains voltage fluctuations - Google Patents

Description

The invention relates to a vertical deflection circuit stabilized against amplitude and mains voltage fluctuations for a television receiver with an amplifier stage for feeding in a deflection current into the deflection winding, with a feedback arrangement to stabilize the deflection current by rectifying the flyback pulses to generate a first DC voltage, whose Size is proportional to the mean amplitude of the deflection current, and with an arrangement for generating it a second DC voltage of opposite polarity that corresponds to the first DC voltage is summarized and applied as a working bias to the amplifier stage.

From the German patent specification 1193 538 is one Line deflection circuit for a television receiver known, in which to stabilize the by an end pentode flowing current has a negative working bias voltage, which is created by rectifying the flyback pulses is obtained by means of a VDR resistor, is applied to the control grid of the pentode. An unstabilized one that is subject to mains voltage fluctuations is attached to the screen grid of the pentode Voltage applied. To stabilize the pentode against these mains voltage fluctuations, becomes a positive DC voltage in addition to the negative DC voltage, which is dependent on the return pulses added, the rectification of a mains voltage-dependent current by means of another VDR resistance is obtained and changes with the mains voltage in such a way that the fluctuations the screen grid voltage can be compensated.

From the German Auslegeschrift 1166 819 is also an arrangement for stabilizing the picture format 'known for television receivers, in which a Grid bias of a line or picture deflection tube by means of a varistor from the horizontal return pulses is won. A further control voltage is superimposed on this direct voltage, which consists of is derived from the line blocking oscillator and is dependent on the mains voltage, and these voltages are additionally combined with the booster DC voltage, which is only indirectly due to the mentioned Varistor is stabilized.

Finally, it is already known, for example, from the German Auslegeschrift 1 046 677- to Compensation of temperature-dependent voltage fluctuations in a deflection circuit temperature-dependent To use resistors. Such so-called thermistors are used for this purpose also used in a preferred embodiment of the invention.

The known stabilization arrangements for deflection circuits do not meet the strict requirements the accuracy, such as that required for color televisions, for example. In particular in the first-mentioned known line deflection circuit, the influence of changes in the Return pulse dependent DC voltage on the grid bias of the tube is relatively low.

The invention has therefore set itself the task of specifying a very stable deflection circuit in which the control sensitivity in the event of changes in the amplitude of the return pulse is improved.

The invention consists in that in a deflection circuit of the type mentioned, the second -, DC voltage through a stabilization arrangement of voltage fluctuations in the DC supply voltage is independent and to increase the control sensitivity depends on the amplitude of the return pulse first DC voltage degrades.

In a further development of the invention, the stability ■ A voltage divider to which the unregulated DC supply voltage is applied with a VDR resistor and a temperature-dependent resistor, their resistance value changes as a function of the applied voltage and the temperature in such a way that an am Voltage divider tapped voltage is stabilized. "Preferably, with the stabilization arrangement Another voltage divider with a temperature-dependent resistor for additional control of the stabilizing working preload coupled.

The invention will now be based on a preferred embodiment shown in the drawing explained.

ao In this embodiment, the stabilizing Working bias to a control electrode of the end tube for the vertical deflection of a television receiver created. This working bias (is determined by a voltage divider from the positive pole of the Derived anode power supply. The voltage divider includes a VDR resistor as a component and as a further component a temperature-dependent resistor, a so-called thermistor. The resulting voltage is applied to a second voltage divider, which divides the series * circuit of a variable resistor and a second VDR resistor contains. The second VDR resistor is also coupled to the output electrode of the vertical end tube so that the The voltage across this VDR resistor as a function of the amplitude of the vertical output signal generated return pulse. This voltage is then passed on to another temperature sensitive Circuit with a second thermal breaker. The output of this circuit provides the desired stabilizing working bias for the control electrode of the vertical output stage The source of the compensated supply voltage is coupled to a sawtooth generator, whereby the vertical linearity is improved. In an associated horizontal deflection circuit is a Means provided which the horizontal image size and the high voltage for the cathode ray tube regardless of changes in the supply voltage keeps constant.

In the drawing are the circuits of the television receiver, which are a picture display device, such as B. deliver signals feeding a picture tube 10, shown schematically as block 11.

This block 11, the so-called receiving unit, contains the usual circuit arrangements which supply video signals to an output terminal L and horizontal and vertical synchronizing pulses to terminals P ₁ and P _2.

From the terminal P ₁ , the horizontal sync pulses are fed to a known frequency control circuit 14 and then to a horizontal oscillator 15 which controls a tube 16 of a horizontal output stage.

The Vcrtikalsynchronimpulse are from the. Terminal P ₂ one designated as a whole by 13

* Vertical deflection circuit with a vertical oscillator tube 18 and a vertical end tube 19 supplied.

3 4

The output terminal with a parabolic waveform of a men V, V assigned to the end tube 19 is fed back to the correspondingly designated transformer winding 46, which is connected to the picture tube 10 in terminals V, V of a vertical deflection winding 20 for being ductively coupled to the transformer winding 42. is. A horizontal oscillator 15 generates a sawtooth vertical oscillator stage which is periodically recurring with the natural frequency of the line frequency containing the oscillator tube 18 by means of the image capture resistor 48. After the adjustment voltage, which is applied via a capacitor 21 and a development of the resistor 48, the actual resistor 22 is then applied to the first control grid of the horizon oscillation frequency through the vertical end tube 16 of a pentode. Controlled with synchronous pulses, which is connected via a Widerdieser end tube 16, a flyback transformer 23 with io stood 49, a capacitor 50, the capacitor 40 several taps, with which a high and the resistor 41 from the terminal P _{2 to} the grid voltage rectifier 24, a saving diode 25 and a ter of the end tube 19 are fed. Booster or energy recovery capacitor 26 The amplitude of the capacitor 36 is coupled, whereby a terminal of the capacitor can be set charging voltage by means of the variable gate 26 and the anode of the diode 25 together at 15 linearity control resistor 37 Positive pole of the anode voltage source (+170 V) the one that is connected to the terminal with one end. The compensated positive winding 17, connected to a horizontal deflection 51, is connected to the output terminals H, H 'tive supply voltage. This on the are via a block capacitor 27 and the voltage appearing on a terminal 51 comes from the plus half of a variable control inductance 28 for 20 poles of the anode power supply, but by means of the horizontal linearity is parallel to a winding of a voltage divider, which has a resistor 53, part of the Output transformer 23 switched. a thermistor 54 and a voltage-dependent The horizontal deflection circuit includes a grain or VDR resistor 55, compensated. Parpensierungs circuit with a voltage-dependent allele to the series connection of the thermistor 54 and gene or VDR resistor 29, which can be connected to the flyback transformer 23 via a capacitor 25 to the VDR resistor 55, a filter capacitor 30. Which is at the junction of the pelt. Via a filter circuit, which contains resistors 53 with the capacitor 56 for connection 31 and 32 and a capacitor 33, a screened DC voltage is added to the first control grid of the end tube 16 and the screen grid of the vertical end tube 19 is applied , variable negative bias applied. A comparable 30, According to a feature of the invention is used for the image width regulation control grid of the output tube 19 to the änderlicher resistor 34 through the resistor is a stabilizing working and the junction of the capacitor 30 is applied between the positive terminal of the anode power supply 41 in the following manner with pretension. The output of the output tube 19 is connected to the VDR resistor 29, so that the bias voltage 35 resistor 58 applied via a capacitor 57 to a VDR-the horizontal output tube 16 is coupled. The connection point can be changed, as will be explained in detail below in detail of the capacitor 57 with the VDR resistor 58. A capacitor 35 is connected in parallel to the VDR resistor via the series circuit of a variable 29. The series circuit lent resistor 59 for adjusting the image height from the capacitors 30 and 35 provides the required: and a fixed resistor 60 provides the compensated positive return capacitance. . 40 tive DC voltage is applied, which is available at the terminal in the vertical deflection circuit 13 at a 51, with which the fixed resistor capacitor 36 is connected to a substantially sawtooth-shaped 60 at one end. A tense tension is created. The voltage divider for temperature compensation, which has a charging current resistor 61 and a thermistor 62 leading to this capacitor, is connected in parallel to the VDR resistor 58 with a variable resistor 37 for 45. A compensator tube 18 and a cathode resistor 39 are connected to the linearity control and a fixed resistor at the junction of the resistor 61 with the 38, while the oscil-thermistor 62 and a cathode resistor 39 are in its discharge current path. effect is then via a resistor 63 as well as the The sawtooth voltage is by means of. a resistor 41 on the control grid of the vertical output tube capacitor 40 and a resistor 41 on the 50 19 effective.

Control grid of the vertical end pentode 19 is applied. The anode of this end tube 19, designated as a whole by 12 or 13, is connected to the corresponding output pole of the anode power supply (+ 170V) via a winding circuit 42 of an output transformer with the plus during operation. transformers, ie the transformer 23 or the. The positive anode current of each corresponding deflection cycle, which fluctuates with the sawtooth voltage applied to the control grid of the end tube 19 55 of the winding 42 during the return range, flows through the transformer winding 42 and voltage pulses of relatively short duration. The amplitude generated in the vertical deflection winding 20, which is connected to the terminals V, V together with these return pulses, is much larger than the amplitudes of the voltages which are applied to the sawtooth-shaped deflection oscillation. 60 corresponding output transformers occur during the lead-in areas of the deflection cycles due to positive feedback from the anode of the end tube. The 19 to the control grid of the oscillator tube 18 via an amplitude of the horizontal and vertical return pulse shaper circuit with a capacitor 43, pulses also depend on the amplitudes of the Ab, a resistor 44 and an integrator 45 are steering currents from which the oscillations in the during the trailing areas Circuit maintained- 65 of the deflection cycles by keeping the appropriate. To the control grid of the oscillator tube 18; output transformers flow. Since the amplitudes of the will also determine the size of the image via a resistor 47 and a trailing current (ie, depending on the individually variable "image capture" resistor 48, a span fall, the height or width) of the image, it depends.

The amplitudes of the return pulses obviously go together with the image size and can do so used, changes in the image size, which are caused, for example, by fluctuations in the mains voltage can be caused to compensate or prevent.

The deflection circuits 12, 13 are therefore provided with devices which changes the amplitudes determine their associated return pulses and then a change to the Control electrode of the associated deflection end tube cause applied bias, with compensating Way changed the gain of this tube and kept the image size practically constant will.

In the horizontal deflection circuit 12, the capacitor 30, the VDR resistor 29 and the speak variable resistor 34 for the image width control to changes in the amplitude of the horizontal return pulses and change the operating values ao (e.g. the grid bias) of the horizontal end tube 16, so that fluctuations in the image width are largely avoided. The VDR resistor 29 exhibits a relatively low resistance value when a high voltage of any polarity is applied at a low voltage of any polarity, on the other hand, a high resistance value. The horizontal output oscillation is transmitted to this VDR resistor 29 via the capacitor 30 created. Since the mean resistance value of the resistor 29 during a positive retrace pulse high voltage is lower than its mean resistance value during the negative trace areas of vibration, it acts as a rectifier of variable effectiveness and develops in Connection to the capacitor 30 in parallel with the capacitor 35 has a negative bias voltage, which 'depends on the amplitudes of the horizontal flyback pulses. Takes z. B. the mains voltage, so the amplitude of the flyback pulse also decreases, which in turn results in a less negative voltage on the VDR resistor 29 leads. Due to the resulting decrease in the negative grid bias the gain of the tube 16 and thus the anode current increases, so that a reduction in the image width, which would otherwise arise is prevented. If the line voltage rises, a opposite compensation effect. Regardless of fluctuations in the mains voltage, so the image width is largely stable.

As a result of the stabilization of the Horizontalablenkschaltuhg 12, the size of the means of High voltage rectifier 24 applied to the picture tube 10 (which is also from the Amplitude of the horizontal return pulses depends) despite fluctuations in the mains voltage kept constant.

The temperature of the deflection winding 20 has a relatively strong influence on its impedance. The winding resistance increases with temperature. Other circuit elements are also in strong Dimensions influenced by temperature. So it is desirable in the vertical deflection circuit 13 to provide temperature compensation. This is achieved by including the compensated Supply voltage source with the series connection of the resistor 53, the VDR resistor 55 and the thermistor 54, which are in parallel with the anode power supply (+ 170V) and a supply voltage supply, in which the influence of mains voltage fluctuations by means of the VDR resistor is largely decreased and in what changes in the temperature of the vertical deflection circuit 13 are compensated. The thermistor 54 should preferably be in the neighborhood or in thermal Connection to the circuit element can be arranged, which is caused by temperature changes being affected. The compensated voltage on terminal 51 is two different parts of the Vertical deflection circuit supplied.

Firstly, the sawtooth generator containing the resistor 37 for the linearity control, the resistor 38 and the capacitor 36 is coupled to the terminal 51. In the event of fluctuations in the mains voltage, the resistance value of the VDR resistor 55 changes, as a result of which the influence of these fluctuations on the voltage at terminal 51 is largely reduced and the vertical linearity is kept practically constant. For temperature variations the resistance value of the thermistor 54 changes, _WO-f by the voltage at the terminal 51 in such a manner comparable \ (is altered in that the vertical linearity also be prevented in this case changes which would otherwise occur, it decreases with increasing temperature the resistance of the thermistor 54, while the voltage at the terminal 51 rises, whereby temperature-related changes in the operating data of the circuit components are compensated for.

Second, the terminal 51 is the circuit arrangement for the grid DC bias of the vertical output tube 19 connected, through the variable resistor 59 for adjusting the image height and resistor 60. At the junction between capacitor 57 and the VDR resistor 58 therefore a positive voltage is applied, which is against mains voltage fluctuations is stabilized and compensated to a certain extent against temperature changes. The condenser 57 and the VDR resistor 58 are similar in their operation to the capacitor 30, and the voltage-dependent resistor 29 of the horizontal (| deflection circuit 12 and lead from the vertical output stage a negative voltage, which is a measure of the amplitude of the vertical retrace pulse. It it is desirable to apply as much as possible of the amplitude of the vertical return oscillation to the VDR resistor 58 to be applied, i.e. to work in a steep range of the VDR characteristic during the return. In this case, depending on the voltage applied, there may be a significant change in resistance can be achieved. When choosing the resulting negative generated at the VDR resistor 58 Stress, however, must also be paid attention to the permissible level of negative prestress, which can be applied to the vertical end tube 19. So that the application of a pulse with a high Level is possible without creating an excessive negative voltage in parallel with VDR resistor 58, is the positive compensated supply voltage via the variable resistor 59 to Adjustment of the image height to the negative voltage at the junction of the capacitor 57 with the VDR resistor 58 added. Changes' in the amplitude of the vertical return pulse will be so highlighted, because a large part of the par-

allele to the capacitor 57 generated, relatively solid DC voltage component is effectively canceled. The resistor 59 for adjusting the image height can be adjusted to include the fixed positive voltage component, i.e. the voltage applied to the end tube 19 applied effective negative grid bias to 'change. The amplification of the end tube and thus the image height can therefore be regulated. Also enables it is the arrangement of the variable resistor 59, expected manufacturing tolerances a component which is used as a voltage-dependent resistor 58 in the circuit supposed to compensate. By setting the resistor 59 accordingly, the influence of deviations between the current-voltage characteristics of different VDR resistors turned off.

A further temperature compensation with regard to the parameters of the vertical deflection winding 20 is by means of of the voltage divider containing the resistor 61 and the thermistor 62 is possible. If the · When the temperature rises, the bias voltage applied to the end tube 19 is decreased, thereby increasing the gain the end tube 19 becomes larger and the image height remains practically constant.

Claims (3)

Patent claims: 1. Vertical deflection circuit stabilized against amplitude and mains voltage fluctuations for a television receiver with an amplifier stage for feeding in a deflection current into the deflection winding, with a feedback arrangement to stabilize the deflection current by rectifying the flyback pulses to generate a first DC voltage, whose Size is proportional to the mean amplitude of the deflection current, and with an arrangement for the generation of a second DC voltage of opposite polarity to that of the first DC voltage is summarized and applied as a working bias to the amplifier stage, characterized in that the second DC voltage through a stabilization arrangement (54, 55) of voltage fluctuations of the. DC supply voltage is independent and to increase the control sensitivity of the amplitude of the return pulses dependent first DC voltage decreases. . 2. deflection circuit according to claim 1, characterized in that the stabilization arrangement a voltage divider (53, 54, 55) to which the unregulated DC supply voltage is applied is, with a VDR resistor (55) and a temperature-dependent resistor (54), whose resistance value depends on the applied voltage and the temperature changes in such a way that a voltage tapped at the voltage divider is stabilized. 3. deflection circuit according to claim 2, characterized in that with the stabilizing arrangement (54, 55) another voltage divider (61, 62) with a temperature-dependent resistor (62) is coupled for additional regulation of the stabilizing working bias. 1 sheet of drawings. 109 617/122