DE1811138A1 - Horizontal deflection system - Google Patents

Description

Horizontal deflection system The invention relates to a horizontal deflection system Deflection system for deflecting an electron beam in a cathode ray tube.

A standard television receiver includes a pair of deflection systems for horizontal and vertical deflection of an electron beam to create a grid to form on the screen of a cathode ray tube. The horizontal deflection system includes a switch that is alternately opened and closed, around a sawtooth current in the set of horizontal deflection windings and around flyback pulses which in turn are rectified to the cathode ray tube to be supplied with a high voltage. To center the grid, it is known Way a direct current is fed into the horizontal deflection windings.

In the known horizontal deflection systems, the centering current flowed and the mean direct current drawn by the horizontal deflection system, in the horizontal deflection windings. Changes in electron beam intensity, which changes in the image brightness are reflected in eich changes in the mean sliding current drawn by the system. Since the mean direct current flowing through the deflection windings was a change in the Brightness undesirably represented as a change in the position of the grid. This is special for the beholder annoying, because the 3ildinhalt constantly changes and thus causes a constant change in the position of the grid will.

It is therefore an object of this invention to provide an improved circuit for the introduction of a centering current in a deflection winding, changes in image brightness have a minimal effect on the location of the Have rasters.

The inventive horizontal deflection system includes a switch, which is connected in series with a capacitance and a deflection winding, to alternately apply the capacitance to the winding and a sawtooth current in of the winding. An inductor applies a direct current voltage to the Switch and has return impulses, which are @rzougt in it as a reaction on the mode of operation of the switch. A rectifier circuit is connected to the inductor and a direct current is applied to the deflection winding for rectification a part of the flyback pulse applied to a direct current component for the To form a sawtooth current.

The deflection windings in a horizontal deflection system are capacitive connected to the arrangement that they suggest to exclude that the middle one Current value drawn by the system, flowing through the windings and around a Linearity correction voltage on the way via the series @ resonance of the deflection winding and the clutch capacitor. A network that runs between the windings is placed, directs the return impulses in the same way in order to Centering current to introduce into the windings, which is essentially independent of the middle Current drawn by the system is.

Further features, advantages and possible uses of the new invention result from the attached representations of exemplary embodiments and from the following description.

The figure shows a television receiver partly as a block diagram and partly schematically, in which the deflection cyst according to the invention is explained.

The color television receiver (figure) contains a receiver circuit 10 for Reception and conversion of the incoming television signals, which are sent to the antenna 12 appear to provide video information for a multi-ray tube 14 produce.

Vertical synchronization @@@@ ulse will be from the video information separated in a Synchronisie @ gssi @ nal separation circuit 16.

These pulses are applied to the vertical deflection system 18, which sawtooth deflection current in vertical deflection windings 20 on cathode ray tube 14 generated.

Horizontal sync pulses generated by the sync signal isolating circuit 16 are derived, are fed to the horizontal control circuit 22 of the usual design, which has a phase detector, an oscillator and a preamplifier for generating a pulsating signal 24 to an inductance winding 26 for use the horizontal output circle 28 may contain. The output circuit 28 closes a resistor 30 and a capacitance 32 which are parallel to each other between the winding 26 and the base of an npn transistor @ i are laid. The other end the Winding 26 and the emitter of transistor 34 are at a point with reference voltage, such as mass. Resistance 30 and capacitance 32 form a self-biasing network, to get a negative voltage so the emitter-base junction of the transistor 34 is operated in the reverse direction. The transistor 34 works as a switch in FIG such that the negative part of the pulsating signal 24 becomes the reverse Bias is added and the switch is opened. The positive part of the pulsating Signal 30 surmounts the blocking bias, so that the switch is closed and the collector of transistor 34 is effectively grounded.

The horisontalon ablon windings 36 on the cathode ray tube 14 are in Roihe with a Kapasit @ t 38 between the Koll @ ktor of the transistor 34 and Earth switched. The sawtooth current 40, which flows through the windings 36, has @in outgoing interval, while electron beams in the cathode @ trahlröhr @ 14 long @ am deflected from left to smelt over the screen of the cathode ray tube 14 to depict the video information. Stream 40 also includes a return interval, while the electron beams flow rapidly to the left of the Rast @ rs. A B ++ voltage, which over the capacitance 42 is connected to ground, is via the primary winding 44 of a high-voltage transformer 46 connected to the collector of transistor 34.

During the last part of the outgoing interval, the tran @ istor 34 driven by d @ n positive T @ il of the pulsating signal 24 in the forward direction b @, to close the switch and the condenser 38 over the deflection windings 36 effectively connect. The capacitor 38 @ ntcharges to the Allow the current in the windings 36 to increase linearly and the last part of the trailing section of the sawtooth current 40 to form. Daa appearing of the negative part of the pulsating Signals 24 puts the transistor 34 in the non-conductive state, so that the Switch is opened and the energy stored in the deflection windings is discharged through a capacitor 48 in a half-wave oscillating manner, to form the return portion of the sawtooth current 40. The negative part of the pulsating signal 24 has a sufficient duration, the transistor 34 during the entire return interval and the beginning part of the forward interval non-conductive to keep. Continuous oscillation is prevented by a line diode 50, which conducts the current through deflection windings 96, around the initial portion of the trace portion of the sawtooth current and to charge the capacitor 38 to a value which exceeds that of the B ++ input voltage. The alternating loading and unloading of the capacitor 38 forms a parabola 52, which has a mean value 53, which equals the B ++ tension. The parabola gives the starting component of the sawtooth current 40 has an S-shape for linearizing the beam deflection. The return pulses 54, which are formed across the primary winding 44 during the retrace interval, are stepped up to be across secondary winding 56 of transformer 46 to appear. The up-transformed pulses are processed by a high-voltage rectifier 58 rectified to provide a high voltage for the end anode 60 of the cathode ray tube 14 to generate.

To center the grid on the screen of the cathode ray tube 14, the rectifier circuit 62 is provided, which includes a potentiometer 64, its movable tap .66 with the connection of the deflection windings 36 and the capacitor 38 is connected. A winding 68 of the transformer 46 has a center tap 70, which via another winding 72 of the transformer 46 with the "upper end @" the primary winding 44 is connected. A diode 78 is between one end of the winding 68 and one end of the potentiometer 64 connected, and a reverse polarity diode 80 is between the other two ends of the potentiometer 64 and the winding 68 switched.

The rectifier circuit 62 forms with the deflection winding 36 and the Winding 72 a series circuit. This series connection is via the capacitor 38 connected to earth, so that the parabola 52 also appears at the tap 70. The potential difference between tap 66 and tap 70 is thus corresponding the parabolic signal 52 is zero. The return pulses 54, which over the Winding 44 appear are transferred inductively to winding 68. A pulsating one Signal 82 appears at the top of winding 68g its mean value 84 is in relation on tap 70 and tap 66 equal to zero. Therefore, the diode 78 is through puts the positive portion of the pulsing signal 82 into the conductive state, and since this portion is shallow and exists for most of the defrost cycle, usually around 85 *, a positive DC voltage appears on the high end of the potentiometer 64, which of the amplitude 86 of the pulsating signal 82 largely is equal to.

In a similar way, the negative part makes one opposite - @@ etzt polarized-pulsating signal 88, which appears at the lower end of winding 68, the diode 80 conducting, so that a negative DC voltage at the lower end of the Potentiometer. 66 appears, which is the amplitude 90 of the pulsating Signals 88 is largely the same. On this. Way becomes a positive voltage at the top End of potentiometer 64 and creates a negative voltage at its lower end. By moving the tap 66, any voltage between them both extreme values can be set. Since the Ablenuungswicklungs 36 effectively between the tap 66 and the tap 70, determines the movement of the tap 66 the voltage drop across the winding 36 and thus also the direct current through it. This direct current regulates the position of the grid and is thus called the centering current designated. Although the baselines of the pulsating signals 82 and 88 are relative are flat, it is desirable to prevent piltering in the form of capacitors 92 and 94 to add. Otherwise the polarity of the diodes 78 and 80 could be reversed will. In this @ case @ie would be the pulsie @@@@ ien due to the momentum component Signals @ and 88 @eiten.

The winding 72 is to G @@@@@@@@@@@@@ oppl @ ng d @@@@@@@@@@ chterkreises 62 to the top @@@ de @ de Abl @@ kwicklungen 36 @necessary. The winding 72 is outside @ that @weudig to prevent the return pulses 54 from appearing on the A @ handle 70. In the present embodiment this is achieved in that the winding 72 is part of the transformer 46 and the windings 44 and 72 are polarized so that that the flyback pulses at the tap 70 are canceled.

Otherwise the winding 72 could be a separate choke coil, which is dimensioned so that it is sufficient.

the return pulses 54 to keep the tap 70 away.

The winding 72 fulfills the double function, the tap 70 to be coupled to the deflection winding 36 with equal currents and also d @@@@ both Isolate points alternately in terms of oil current.

As soon as the mean intensity of the electron beams in the cathode ray tube 14 increases, which is due to a change in the G @ halt of the video information from the recipient group 10 or an increase in the tension on the cathode ray tube 14 can occur, the mean current drawn by B ++ through winding 44 increases proportionally at. Because the deflection windings 36 are capacitively coupled to the winding 44, flows such an additional portion in the mean current is not due to the deflection windings. Therefore a change @@@@ g in the mean beam intensity influences the position of the grid not. That is, two separate direct current leads are created. By doing first is rectifier circuit 62 across windings 36 through winding 72 connected, and the @ ittl @ r @ Strom @ d @ r Z @ ntrierung @ str @ m, who fli @@@, is determined by setting the potentiometer 64 @ to determine the position of the grid fix @ g @ n. The second @@@@@@@@, @ r includes the winding 44 and the transistor 34, and @@@@@@@@@@@@@@@@ current, which reflects the beam intensity, @@@@@@@@@@ this Path. The tours are largely independent - @@@@@@@@@@ @@ n @ in one another, so a change in the middle system - @@@@@@ @@@@ Z @ ntrierungsstrom not b @ influences. this is a @ @@@@@@ de V @ r @@ sserung compared to earlier versions of Z @@ tri @ rmmgsschaltungen, inside the middle direct current @@@ the ignition current through the deflection winding rivers.

@@ @@@@@@ ask for a v @ rb @ sserte Easterzentri @@ ungs - @@@@ alt @@@@ @@ w @ lcher the influence on the centering current, wel @ her from changes in the mean Brightness of the picture @@@ @@@@, @@ f @@@ Minimum dimension is v @ rri @ g @ rt.

Claims (6)

Claims 1. A horizontal deflection system for deflecting an electron beam in a cathode ray tube characterized by a deflection winding (36), a capacitor (38) and a switch (34) which are connected in series, and an inductance (44) which applies a DC voltage to the switch (34), further characterized by a circuit (22, 26) for alternating opening and closing the switch to a sawtooth current in the winding (36) and flyback pulses in the inductance (44) to generate a rectifier circuit (62) which is operational is connected to the inductance (44) and a direct current which is fed to the Deflection winding (36) is placed to rectify part of the flyback pulses, to generate a direct current component for the sawtooth current. 2. Horizontal deflection system according to claim 1, characterized by a rectifier circuit with a potentiometer (64) with a movable tap (66) and a further inductance (68) with a tap (70) which is inductive coupled to the inductor (44) and characterized by an erete diode (78), which between the one end of the further inductance (68) and dqe a The end of the potentiometer (64) is switched and polarized in one direction, and one second diode (80), which between the other end of the further inductance (68) and the other end of the potentiometer (64) switched and in opposite Direction is polarized, and further characterized by an arrangement (72) which connecting the deflection winding (36) between the tap (66) and the tap (70). 3. Horizontal deflection system according to claim 2, characterized in that that the arrangement which the deflection winding (36) between tap (66) and tap (70) connects, another inductor (72) contains. 4. Horizontal deflection system according to claim 3, characterized in that that the rectifier circuit (62) further comprises a pair of filter capacitors (92, 943, which are connected in series and via the potentiometer, with the Connection of the capacitors (92, 94) to the tap (70) of the further inductance (68) is connected. 5. Horizontal deflection system according to claim 1, characterized in that that the switch includes a transistor (34) which has a pair of output electrodes and a row diode (50) is connected across the output electrodes, wherein the row diode (50) and the output electrodes with the inductance and the capacitance are connected in series. 6. Horizontal deflection system according to claim 1, characterized in that that the switch comprises a transistor (34) with a first and a second output electrode contains, wherein the first output electrode is connected to a ground reference potential, and characterized by a row diode (90) which extends across the output electrodes is laid, a transformer (46) with a first (44), second (56), third (68) and fourth (72) winding, with the first @ winding (44) between the second Output electrode and the DC voltage (B ++) is applied, and the deflection winding (36) and the capacitance (38) in series between the second output electrode and the Earth reference voltage are placed, further characterized by a Gletohrichter arrangement (58), which are connected to the second winding (56) for rectifying the return pulses is to generate a high voltage for the cathode ray tube (14), and a Potentiometer (64) with a tap (66) which is connected to the connection of the capacitance (38) and the deflection winding (36) is connected, the third winding (58) having a Tap (70) has, but the @@@@@@ winding (72) with the second output electrode @@@ is bound, and further identified by a @@@@@ e diode (73), which between one end of the @@@ ten winding (68) and the @ @@ end of the potentiome - @@@ 64) switched i @@@ and @@@@@@@ second Di @ de (80) @@@@ e between @ n @ as and @@ e end @@ er dratten W @@ klung (68) @@@@@@@ anders @@@ de des @ totent @ ter @ (64) ge @@@@ L. e e r e i t e