DE2851081C2 - Deflection circuit - Google Patents

Description

The invention relates to a deflection circuit according to the preamble of claim 1.

Such deflection circuits are from radio mentor electronic, volume 43, 1977, issue 3, page 113 and from MJNKüuHAU, year 49, 19 ??, issue 18, pages 832 to 834 known The deflection circuits described there are complex, based on the principle of switched Amplifier-working deflection circuits comprising vertical deflection and horizontal deflection.

Such deflection circuits have the disadvantage that the pulse stage is supplied to the line pulses and from which the line-frequency pulses are taken from a defined sloping ceiling, a strong temperature dependency has, so that the line-frequency pulses of defined pitch in their amplitude and in the phase positions of their flanks depend in an undesirable manner on the temperature.

The invention is therefore based on the object of avoiding such a temperature-dependent dependence of the pulse stage.
According to the present invention, this object is achieved in that a shunt diode is arranged at the input nt r pulse stage, a series diode is connected downstream of the shunt diode in the signal path of the pulse stage, electrodes of the same type of the shunt diode and the series diode are galvanically connected to one another and the line-frequency pulses of defined roof slope to the free Connection of the series diode can be removed by means of an integration stage.

According to an advantageous embodiment of the present invention, a deflection circuit can be used from which the currents flowing through the horizontal deflection coil are taken from the horizontal output stage by one in a branch of the Horizontalablenkspu-It arranged controllable switch of the in their Wide vertical frequency modulated line frequency output pulses of a control stage, at whose line frequency Input pulses of a defined sloping ceiling are pending, switched conductive, therefore essential improve that the output of the integration stage, which defines the line-frequency pulses of sloping roof can be removed, is connected to the line-frequency input of the control stage.

According to an advantageous embodiment of the invention, the line-frequency pulses can be defined more precisely Obtain sloping ceilings in a simple way by means of an integration stage by the free connection of the Series diode is connected to a tap of a voltage divider, one branch of which is a shunt forms in the signal path of the impulse stage, the high point of the

other branch of the voltage divider is connected to a voltage source and the input of the integration stage is connected to a tap of the voltage divider.

Advantageous training at the integration level erger .en from the subclaims.

The temperature stability of the deflection circuit can be adjusted in a simple manner according to advantageous embodiments of the invention by i that the shunt diode and the series diode coincide in their flux savings and are thermally coupled to one another are.

The shunt diode and the series diode be galvanically connected to one another on the cathode side.

The advantages of the present invention are particular that when using a deflection circuit designed according to the invention, the image height and the Image width of the component and the ambient temperature are v / e time-out independent, so that a Excellent, stable image quality results. These advantages can be achieved without significant additional effort achieve.

The invention is subsequently applied to the F i ^. 1 and 2a to 2e explained in more detail

F i g. 1 shows a deflection circuit constructed in accordance with the invention

F i g. 2a and 2b show the line pulses at the input of the pulse stage and at the high point of the bypass diode a pulse stage designed according to the invention. the

F i g. 2c, 2d and 2e show the voltage profile assigned to the line pulses at different Measuring points at the integration stage of the pulse stage designed according to the invention.

In FIG. 1 shows H the horizontal output stage, to which the primary winding Wi of the flyback transformer Z is connected. The flyback transformer Z also has the secondary windings W2 and Wz , which are powered by the controllable switches switched by the control stage Si and in this example designed as thyristors Ή12 and Ή13 the vertical deflection coil Lν is taken. For this purpose, the thyristors 77? 2 and Th-} are controlled by line-frequency right-hand pulses, the width of which is modulated with vertical-frequency sawtooth pulses, in such a way that the pulses that control a thyristor are initially wide and gradually become narrower, while the change in width of the other thyristor controlling pulses runs in the opposite direction.

Because of this switching of the thyristors ΓΛ2 and Thi , the capacitor G is charged and reloaded in such a way that the vertical deflection current flows through the vertical deflection coil Lv and the circuit 5 for correcting the geometry

To this end, the control circuit Si is supplied with the vertical-frequency output pulses from the sawtooth generator Gv and line-frequency output pulses from a defined slope of the pulse stage /.

The voltages for operating the horizontal deflection coil Lh are also taken from the horizontal output stage H. For this purpose, the horizontal deflection coil Lh can be used in a manner known from the prior art and shown in FIG. 1 not shown in detail with the .Zeilentrafo Z primary side connected.

The horizontal deflection coil Lh is connected via a tap formed by the inductances L < - and Li and the capacitor Cs to a switch, which in this exemplary embodiment is formed from a thyristor Th \ with an anti-parallel diode D% .

The thyristor Th \ is switched by the control stage Si via the control electrode with line-frequency square-wave pulses, the width of which is modulated vertically-frequency parabolic

For this purpose, the line-frequency impulses defined at an output of the pulse stage / pending line-frequency impulses of the control stage S2 are fed to the line-frequency input of control stage S2. Furthermore, the output pulses of the vertical frequency sawtooth generator Gv are applied to the vertical frequency input of the control stage Si .
At the output of the generator, the Zailenimpuls confess, as in the F i g. 2a shown. These line pulses are passed through the matching resistor R _x to the high point 1 on the cathode side of the shunt diode Di. The high point 1 on the cathode side of the shunt diode D \ is connected to the cathode of the series diode L \ . At the high point 1 of the shunt diode D \ occurs in FIG. 2b shown voltage curve. The free, anode side! ';? Connection of the series diode Di is connected to the tap 2 üss voltage divider formed from the resistors R2, R3 and Ra. The high point B of this voltage divider forms the connection point for a voltage source of positive polarity, not shown in detail. The partial resistance kj and the partial resistance formed from the series connection of the resistors Ri and R2 are followed by the capacitors Ci and C * acting as integration stages. 2d and 2e shown voltage curve.

As can be seen from FIGS. 2c to 2d, line-frequency pulses with a defined roof slope occur at measuring points 2, 3 and 4. The measuring points 2 and 4, from which pulses of defined rising roof pitch can be taken, are connected to the line-frequency inputs of the control stages S2 and S \ .

The impulse level / works as follows. When applying the return pulse. Point A in the F i g. 2a to 2e, a current flows from measuring point 2 into the input of generator Gh until the voltage of the flyback pulse rises to the value of the sum of the voltage drop across resistor R3 at measuring point 2 and the forward voltage of series diode D2.

The series diode D2 then blocks. With the voltage- related zero crossing, point B, of the line pulse, the positive forward voltage of the series diode D2 is present at measuring point 2.

During the line feed, measuring point 1 is clamped by the shunt diode D \ to the negative forward voltage of the shunt diode D \. At measuring point 2, the voltage thus falls to the value zero, provided that the shunt diode D \ and the series diode D2 have the same forward voltages? = I. Thus, the voltage at measuring point 2 remains at a constant value independent of temperature, namely zero, during the entire line advance. When the line-to-line pulse reaches zero at the beginning of the line trace, the capacitors C \ and Cj are discharged. After the voltage-related zero crossing of the line impulses at the end of the line advance. the capacitors C \ and Ci are charged again during the line retrace, so that at the measuring points 2, 3 and 4 of the FIG. 2c, «ri and 2e results in the voltage curve shown.

X \ s * _r χ

Due to the arrangement and dimensioning of the diodes according to the invention, the line-frequency pulses defined roof slope in the positions of their front and rear flanks as well as in their amplitude curve temperature independent.

The Fig.2a to 2e show the voltage curve on Input of the pulse stage as well as at the measuring points 1 to 4. In the F i g. 2a to 2e correspond to one another points of the curves lying at the same point in time.

The concave course of the shown in Figure 2e Roof slope is required for the formation of an S-shaped vertical deflection flow.

A pulse stage designed according to the invention is characterized by a simple structure and can be form an integrated circuit or a hybrid | 5 circuit.

In the inventive manner, in particular, all deflection circuits can form, having a vertical deflection circuit, supplied in which during a first Zcitspsnns the Vsrtikslsbienkun ⁰ zunshnisncl decreasing portions of the energy of the Horizontalablenkwelle and during a second period of the vertical deflection increasingly widening portions of the energy of the Horizontalablenkwelle the vertical deflection to generate the sawtooth-shaped vertical deflection current.

For this purpose 2 sheets of drawings

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I. B.

Claims (9)

Patent claims: 1. Deflection circuit for television receivers with a horizontal output stage and a vertical deflection coil, which is connected to the horizontal output stage via at least one controllable switch and in which the controllable switch is controlled by a control stage, at whose inputs the output pulses of a vertical frequency sawtooth generator and the line-frequency output pulses of a defined pitch of a pulse stage , to which line pulses are supplied, are pending, with line-frequency pulses modulated with vertical frequency in their width to form the vertical-frequency deflection currents in the vertical deflection coil, characterized in that a shunt diode (D [) is arranged at the input of the pulse stage (!) , the shunt diode (Di) is connected in the signal path of the pulse stage (I) a Längsdioöe (D _2), the same type of electrodes Nebenschiußdiode (Di) and the series diode (Di) are electrically connected together and the line rate pulse e defined sloping roof can be removed from the free connection of the longitudinal diode (D ₂ ) by means of an integration stage. 2. Deflection circuit according to Claim 1, in which the currents flowing through the horizontal deflection coils are taken from the horizontal output stage by a controllable switch arranged in a branch of the horizontal deflection coil from the line-frequency output, which is modulated vertically in its ureite, simpi ^ en of a control stage at whose line-frequency input Pulses defined sloping roof is switched conductive, characterized in that the output of the integration stage (I), from which the line-frequency pulses of defined sloping roof can be taken, is connected to the line-frequency input of the control stage (S ₂ ) . 3. Deflection circuit according to Claims 1 and 2, characterized in that the line-frequency pulses of defined pitched roof can be obtained by means of the integration stage by connecting the free connection of the series diode (D ₂ ) to a tap (2) of a voltage divider (R ₂ , Rz , A4), one branch (Ri, Ra) of which forms a shunt in the signal path of the pulse stage (I) , the high point: (B) of the other branch (R ₂ ) of the voltage divider (R ₂ , Rz, A4) with a Voltage source is connected and the input of the integration stage is connected to a tap of the voltage divider (R ₂ , R), Ra) . 4. Deflection circuit according to claim 3, characterized in that the integration stage is formed by an ÄC element (Rs, C ₂ ) which is connected in parallel to a partial resistance of the voltage divider (R ₂ , R}, R4). 5. Deflection circuit according to claim 3, characterized in that the integration stage is formed by a capacitor (Q) which is connected in parallel to a partial resistance (Rj) of the voltage divider (R ₂ , R3, R *). 6. deflection circuit according to claims 4 and 5, characterized in that the base (3) of the Konde'nsators (Q or C ₂ ) of the integration stage with a tap of the branch forming the shunt (R ₃ , Ri) of the voltage divider (R ₂ , R3, Ra) connected that is 7. deflection circuit according to claims 1 to 6, characterized in that the shunt diode (Di) and the series diode (D ₂ ) match in their forward voltages. 8. deflection circuit according to claims 1 to 7, characterized in that the shunt diode (Di) and the series diode (D) ₂ ) are thermally coupled. 9. deflection circuit according to claims 1 to 8, characterized in that the shunt diode (Dt) and the longitudinal diodes (D ₂ ) are galvanically connected to one another on the cathode side.