DE1462927C - Self-oscillating vertical deflection circuit for television receivers - Google Patents

Description

The invention relates to a self-oscillating desire to predistort the deflection current in an S-shape, vertical deflection circuit for television receivers with a compression of the image at the one transistor amplifier, the output terminal of which will avoid edge areas. In order to detect this the deflection winding is connected and overreach, in the deflection circuit between a negative feedback output containing a Miller capacitance and an input of the transistor amplifier a further path can be fed back to its input connection, “two. series-connected integra, and whose input terminal is connected to a feedback branch containing control elements vqrge switching transistor that the Miller can be seen. As a result, the curve shape of the capacitance is predistorted in the desired manner with the input terminal of the amplifier io when the switching fan is blocked via a generated image deflection current. · _;

connected impedance charged, with conductive The invention is described below with reference to the in

Switching transistor, however, is discharged via this, the embodiments shown in the drawings and in the case of the output terminal of the · explained in more detail. It shows

Transistor amplifier via a resistor F i g. 1 is a greatly simplified circuit diagram of a

having feedback path. the control 15 television receiver with one according to the invention electrode of the switching transistor a time selection formed vertical deflection circuit and signal for the synchronization process is coupled, Figure 2 is a circuit diagram of a modified alternative, the reverse bias of the control electrode guide form of the in F i g. 1 shown deflection End of the trace interval of the deflecting saw circuit, tooth reduced. 20 In Fig. 1 are those for feeding a picture tube 10

It is known in vertical deflection circuits, for the serving stages of a television receiver, with utilization of the Miller effect, an integration would take the horizontal deflection circuit 14 and the capacitor in a feedback line, add vertical deflection circuit 16, through a block 12 and for linearization of the charging current shown at its output terminal L a luminous integration capacitor to provide additional feedback 25 density signal and at its output terminals P ₁ coupling circuits. With the help of further and P ₂ horizontal or vertical synchronizing pulses feedback branches will occur in this known .. The horizontal deflection stage 14 feeds the Hori circuit that is on the control electrode of the switching zontal deflection coils H, H ', the more precisely shown transistor blocking potential towards the end of the Vertical deflection stage 16 feeds vertical deflection sawtooth rise by applying a time selection 30 V, V.

Signal so reduced that the within the Selek- Before discussed the invention itself

tion interval occurring synchronization pulses should briefly refer to the operation of the in Fig. 1 take effect and initiate the line return vertical deflection circuit shown be able. During the remainder of the sawtooth will be.

down has the potential at the control electrode of the 35. The vertical deflection circuit 16, on the other hand, supplies a saw switching transistor with a value which prevents a missing-tooth-shaped current through the vertical deflection synchronization caused by interference pulses. len V, V of the deflection coil set of the picture tube. the

The object of the invention consists in a coils V, V are in series between 'a self-oscillating vertical deflection circuit of the type mentioned a terminal 5+ of a DC voltage source of the reception is to make the circuit insensitive 40 and a coil input terminal Y against interference pulses and the same - tet. The desired sawtooth-shaped current in.den at the time the starting point of the power line of the switching deflection coils, which during the run, i.e. transistor to stabilize the image state very much during the long flank of the sawtooth, to be precisely defined. will appear essentially as a real resistance

According to the invention, this object is achieved by a sawtooth-shaped voltage at which the output voltage of the transistor terminal Y is generated. This sawtooth-shaped clamping Stärkers is removed transformer and voltage is supplied by a transistor circuit of the so-called Miller Integra parabolic path than about via the integrating feedback acting on the principle of the base of the switching _transistor:; tors works. ■ -....; ... _t ; ^ y.,. - _; -, .'_>. A ->, .- -li; ,,:, ',,'.;.;_:; - / shaped voltage is supplied, the steeper, with 50 'The deflection circuit 16 contains three transistors with the aid of the resistor in its inclination adjustable 20, 40, 60, which are connected in series and section determines the synchronization selection interval of the one amplifier with a high current gain switching transistor . - form. The amplifier output is connected to the amplifier

The steep section of the connection from the sawtooth clamp input via a negative feedback path with the aid of the integration elements of the rear end, which contains a capacitor 80. The decoupling path generated parabolic voltage of the amplifier at the Y terminal leads to a more precisely defined time due to the Miller integrator principle at the switching point of the switching transistor, since the switching-on essentially linear sawtooth voltage for this transistor of the steep to the input terminal of the marked O

Parabola load faster. is traversed as a 60 amplifier is connected to a transistor 90, the linear voltage. With the help of the setting in the conductive state, the terminal O, which can be connected to the base ble resistor, the course of the steep 23 of the transistor 20 is somewhat short-circuited with the B + section of this parabolic voltage. If the transistor 90 blocks, on the other hand, vary, so that the point in time of the passage of the stage containing the transistor 90 for the switch-on voltage of the switching transistor changes 65 Terminal O can become a practically infinite resistance: In this way, the image capture can be shown. The transistor 90 is periodic and swing regulicren. flow-like between the blocked and the lead

For picture tubes with a large deflection angle, the state is switched by switching the

one

output transistor 60 of the amplifier cooperates in the manner of astable multivibrators.

The multivibrator effect occurs because the output electrode (collector 95) of the transistor 90 to the input electrode (base 63) of the transistor 60 via the transistors 20, 40 and the output electrode (Collector 65) of transistor 60 with the input electrode (base 93) of transistor 90 are coupled via a feedback resistor 100 in a positive feedback path.

The synchronization of the multivibrator oscillations is carried out by vertical synchronization pulses, which are sent from the terminal P _{2 of} the base 93 via a resistor 92 to which a capacitor 94 is connected in series.

cause so that only a single phase inversion takes place in the feedback loop, namely in the stage including transistor 60.

To explain the circuit arrangement described so far, the emitter amplifier stages 20, 40 should first be disregarded, so it is assumed that the terminal O is connected directly to the base 63 of the output transistor. When the transistor 90 is blocked and the Tranlo sistor 60 conducts accordingly, there is a charging circuit for the capacitor 80 between B + and ground, which leads in series to the conductive output transistor 60, the blocking capacitor 68, the resistor 82, the capacitor 80 and the variable resistor will. The feedback resistor 15 stood 84 contains. If the resistor 84 is a 100 between the deflection coil input terminal Y has a large resistance value compared to and the junction of the resistor 92 with the resistance value of the resistor 82, the capacitor 94 is definitely connected. Between this he primarily the charging speed and connection point and B -f · is an i? C-member formed- can then conveniently be used to adjust the grid height tet, which consists of a resistor 101, which is used by a ₃ o by hand.

Capacitor 103 is bridged, there is. This negative feedback acts on changes in potential

.RC element is used for pulse shaping by partially integrating the oscillation fed back from terminal O during the charging period against terminal Y. The current through resistor 84 is therefore integrated. It also prevents disruptions from being reasonably constant. By such a relatively fed back pulses of the line frequency, the constant charging current in 25 a high degree of undesirable manner through the Hörizontalablenk- linearity of the resulting sawtooth voltage coils are induced in the vertical deflection coils. The loading time constant is because of the can. dynamic action of the amplifier, which

The transistor 20, as an emitter amplifier, is connected to the capacitance of the capacitor 80 by one factor, its emitter 21 is multiplied by a factor dependent on the gain via an emitter resistor 30, 26 is connected to B +. The transistor 40 forms one
second emitter amplifier stage, which acts as an emitter load for the emitter amplifier transistor 20.
The base 43 of transistor 40 is directly connected to the

substantially greater than the actual values of capacitor 80 and resistor 84 correspond would.

When transistor 90 conducts, the Trani blocks

Emitter 21 connected, and the emitter 41 of the transistor 60, and there is a discharge circuit for the con-

sistors40 is connected to ß + via an emitter resistor 46. The collector electrodes 25, 45 of Emitter amplifier transistors are connected to one another at a tap of a low-resistance voltage divider

capacitor80 is formed which includes the conductive transistor 90, the capacitor 80, the resistor 82 and the deflection coils V, V in series . The discharge rate is primarily due to

connected, the 40 determines the resistor 82 connected between B + and ground. Since the resistor 82 is tet. This voltage divider consists of resistors 32, 34 connected in series as assumed, which is smaller than the resistor 84, the collectors are also the discharge time constant significantly shorter 25, 45 are with the connection point of this resistance than the charge time constant.

stalls connected. From this somewhat simplified explanation is

The output signal of the series-connected 45 can be seen that the periodic switching of the tran-emitter amplifier stage is fed to the base 63 of the output transistor 90 between the conductive and the blocked transistor 60, which is directly connected to the th state on the capacitor 80 and thus on the emitter 41 connected is. The emitter 61 of the Tran terminal Y with respect to ground, a voltage in the transistor 60 can be maintained via a resistor (resistance in the form of an essentially linear sawtooth 62, FIG. 2), which will be discussed in more detail below that are connected to B + in the deflection coils V, V den. Lets the desired sawtooth-shaped current flow between the collector, since 65 of the transistor 60 and ground there is a constant current path, these windings practically represent a real resistance, current-permeable current path, which is via a primary.

winding 69 P of the transformer 69 leads. However, the circuit can only be used in the

the collector 65 and the emitter 61 there is a 55 working manner when the transistor configuration

AC path that contains a DC blocking block capacitor 68 and the vertical deflection coils V, V in series. The coil input terminal Y is located at the connection point of the blocking capacitor 68 with the coil V.

Terminal Y is connected to the input at the base of transistor 20 via a feedback path that includes a capacitor 80 in series with a resistor 82. The base 23 of the amplifier of the terminal O presents a very high input impedance. There are special transistors that naturally have a high input impedance, but the input resistance of the usual junction transistors is relatively low. Thus, if an ordinary transistor were used for transistor 60 and it were the only amplifying device in the feedback loop, its relatively low input impedance would be

uh

sistor 20 is a variable resistor 65 charging the capacitor in the desired

84 connected to ground. The feedback via the capacitor 80 is a negative feedback, since the Emitter amplifier stages 20, 40 no phase reversal

Way to prevent. However, this difficulty is eliminated here by the fact that between the terminal O and the input at the base of the trans-

sistor 60 two emitter amplifier stages are switched on. The input impedance at terminal O is then very high, since it corresponds to the input impedance of an emitter amplifier whose emitter load contains a further emitter amplifier, which in turn has the input impedance of transistor 60 as an emitter load. This combination results in an input impedance that is sufficiently high to ensure the desired course of the capacitor charging.

The emitter amplifier stages 20, 40 also contribute to the current amplification in the negative feedback loop, so that an amplifier with a high current gain factor is available. This will make the

1, the base 23 of an emitter amplifier transistor 20 is connected to the terminal O , which controls a second emitter amplifier transistor 40, which is then followed by the output stage with the transistor 60. The deflection coils V, V are as in FIG. 1 connected in series with a blocking capacitor 68 between B + and a point of the collector circuit of the output transistor 60.

ίο The input terminal Y at the connection point of the capacitor 68 with the coil V is connected to the base 23 of the transistor 20 via a negative feedback branch which contains the sawtooth capacitor 80. Terminal O is connected to ground via a

Capacity multiplication effect of the circuit increases. i ₅ resistor arrangement connected, which contains the variable resistance 84 and other resistances, problems with regard to instabilities and / or costs, due to this capacitance multiplication effect. As with F i g. 1, the transistors 60 and 60 are avoided, which when using an electrolytic capacitor with a large capacity as a sawtooth capacitor when using an electrolytic capacitor 90 in the manner of a multivibrator, and the oscillations will occur due to the synchronizer. The effect of a 20 synchronized _{pulse from terminal P 2 is achieved here.} Capacitor of large capacitance, although that for the feedback that belongs to the Miller integrator

at F i g. 2 in series with the capacitor 80 a resistor arrangement which contains a fixed resistor 130 which is bridged by a thermistor 131. As is known, a thermistor is a resistor whose resistance value is highly temperature-dependent an impedance is formed which changes automatically with temperature fluctuations and eliminates interfering temperature influences on the deflection linearity.This feature is explained in more detail in a simultaneous proposal, there is also discussed in more detail on further stabilization measures, which are in the connection

for feedback of a signal to the input of the 35 emitter resistors 26, 46 to a terminal B + -f switching transistor 90. The through this feedback there is a higher DC voltage than an auxiliary supply path to the base 93 of the terminal B + . This measure improves vibration, the temperature stability of the circuit of the transformer 69 is also removed by a secondary winding 695. This oscillation ensures that the transistor 60 also under the condition that the shape of a sawtooth plus a 40 blocks the most unfavorable temperature influences when the return peak, the transistor 90 conducts to the base 93 of the transistor.

sistors 90 back via a resistor arrangement at F i g. 2 is coupled to serve as a pitch regulator, which includes a variable resistor 110, the variable resistor 84, a fixed resistor in series with a fixed resistor 111 . stand 85 connected in series, which is used to limit the setting range by this resistor arrangement is 45 together. The series connection of the resistors 84, 85 with the capacitance present at the base 93 also connects the picked-up oscillation in an integrated manner, so that at the terminal O not directly with ground, but with the base 93 an essentially parabolic oscillation- a tap of a voltage divider, that occurs from the movement. This oscillation runs in the vicinity of a series connection of a voltage-dependent resistor at the end of the deflection part of the period ratio (VDR) 140 and a fixed resistor 141 moderately steep and makes the point in time at which it exists. The base 93 of the transistor 90 is conductive via transistor 90, largely inde- pendent of a base resistor 142 also at the tap depending on external influences, eg. B. glitches connected to this voltage divider. This or changes in circuit parameters. The part of the oscillation which is the deflection amplitude against the mains voltage part can be made insensitive by fluctuations. This noting affect variable resistor 110 , which is therefore explained in more detail in another simultaneous proposal as a manually operable grid capture controller.

Can be used. The circuit of FIG. 2 also includes a

F i g. 2 shows a modification of the one shown in FIG. 1 represents diode 150, which with its cathode connected to the vertical deflection circuit 16. As far as the connection point of the sawtooth capacitor 80 with the were possible in FIG. 2 for corresponding or discharge resistor 130 is connected. The anode components with the same effect have the same reference as the diode 150 is used via an i-C element with a B + symbol as in FIG. 1. The one shown in FIG. The i? C element contains a capacitor-provided circuit contains some features, the 151 large capacitance value, which is suggested by a series at the same time elsewhere, 65 circuit from a variable resistor 152 which is connected when these features are mentioned and a fixed resistor 153 bridged is. will give. The circuitry including diode 150 acts as a

The basic structure of the in F i g. 2 shown clamping circuit and prevents the

Capacitor 80 component used to be a relatively small, stable, and inexpensive paper capacitor can, whose capacitance is 0.1 microfarads, for example. - -

According to the general description - that in FIG. 1 The circuit shown can now be used to control the timing of the processes in the circuit that represents the actual subject matter of the invention.

Except for the main feedback branch containing resistor 100 through which the vibrations are entertained, contains the in F i g. 1 shows a further current path

Raster due to oscillations of the feedback amplifier 20, 40, 60 at a subharmonic of the vertical deflection frequency. The variable resistor 152 of this circuit can serve as a linearity regulator. Further details are contained in a simultaneous proposal. In this proposal, the function of a capacitor 160 is also discussed in more detail, which is connected between the collector 25 and the base 23 of the transistor 20 and is used to suppress high-frequency interfering oscillations. Another stabilization that is part of this proposal consists in the use of the very small resistor 62 in the emitter line of the transistor 60. The resistance of the resistor 62 is so small, in practice less than 1 ohm, for example, that it does not have any during normal operation has a noticeable impact. However, if transistor 60 tends to block in the highly conductive, saturated state when the receiver is switched on, a voltage drop of sufficient magnitude occurs across this resistor, which is fed back to the base of transistor 90 via winding 695 in series with resistors 110, 111 and initiates the multivibrator oscillations.

At F i g. 2, the deflection coil arrangement also contains additional components 170, 171, - 172. The resistors 170, 171, which each bridge a deflection coil V, V , are used in a known manner for damping. A thermistor 172 connected between the deflection coils, through which the coil current flows, stabilizes the deflection current amplitude against temperature influences which influence the resistance of the deflection coils. This measure is known from US Pat. No. 2,900,564, for example.

The collector-emitter path of the output transistor 60 is connected in parallel to the contactor with a voltage-dependent resistor (VDR) 64. The voltage-dependent resistor 64 limits the amplitude of return pulse peaks between the coil 61 and the emitter 65 when the transistor 60 blocks. At maximum voltage, the voltage-dependent resistor 64 has its lowest resistance value and thereby dissipates the peak current to a considerable extent, thereby avoiding the simultaneous occurrence of high voltages and high currents on or in the transistor and thus possible damage.

The control of the timing takes place at F i g. 2 practically in the same way as in FIG. 1. The auxiliary oscillation obtained by the transformer 69 is fed back via the resistor 110 serving as a trapping regulator and the resistor 111 to the base 93 of the switching transistor 90 and controls its switching, as described above. The connection of the winding 695 to B + via the small emitter resistor 62 does not disturb the function of this feedback.

The circuit of FIG. 2 includes yet another feature that is not included in FIG. This feature relates to the problem of making the course of the deflection current S-shaped, ie slightly rounding the ends of the sawtooth-shaped current in the deflection coil in order to obtain a linear raster deflection on the screen when using a picture tube with a relatively flat screen. In order to achieve this S-shape, vertical pulses occurring at terminal Y are fed back to the input of the Miller integrator amplifier, that is to say to base 23 of transistor 20, via a suitable shaping network. This network contains three resistors 120, 121, 122 which are connected in series between the terminal Y and the base 23 in the order given. A capacitor 123 is connected between the connection point of the resistors 120, 121 and B + , and a capacitor 124 is also connected between the connection point of the resistors 121, 122 and B +. The network 120 to 123 generates a doubly integrated version of the vertical pulse oscillation for the input of the amplifier 20, 40, 60. When integrated by the amplifier, this oscillation results in a voltage at the deflection coils V, V, which the desired S-shaped current in the deflection coils lets flow.

Circuit parameters for the in F i g. 2 are in one of the above-mentioned circuits simultaneous suggestions given.

Claims (2)

Patent claims: 1. Self-oscillating vertical deflection circuit for television receivers with a transistor amplifier whose output connection is connected to the deflection winding and is fed back to its input connection via a negative feedback path containing a Miller capacitance and whose input connection is connected to a switching transistor in such a way that the Miller capacitance when the switching transistor is blocked charged via an impedance also connected to the input terminal of the amplifier, but discharged via this when the switching transistor is conductive, and in which a time selection signal for the synchronization process is coupled from the output terminal of the transistor amplifier via a feedback path having a resistor to the control electrode of the switching transistor, which the Reverse bias of the control electrode reduced towards the end of the trace interval of the deflection sawtooth, characterized in that the output voltage of the transistor amplifier (20, 40, 60) is removed by transformer (transformer 69) and is fed via the integrating feedback path (110, 111, input capacitance of switching transistor 90) to the base of switching transistor (90) as an approximately parabolic voltage, the steeper of which, with the aid of the Resistance (110) in its inclination adjustable section determines the synchronization selection interval of the switching transistor (90). 2. Vertical deflection circuit according to claim 1, characterized in that for the S-shaped predistortion of the deflection sawtooth between the output (65) and input (23) of the transistor amplifier (20, 40, 60) another, two integration elements connected in series (120,123; 121,124) containing feedback branch (68, 120, 121, 122, 123, 124) is provided. 1 sheet of drawings