DE2753126A1 - Vertical deflection circuit control for TV receivers - has two diodes between transistor bases, shunted by capacitor, with one base connected through resistor to supply voltage - Google Patents

Abstract

The circuit delivers a positive and negative output current and has push-pull power output stages. The control circuit (5) is directly connected to the base of a transistor (7) in the push-pull output stage (6, 7). Two diodes (3, 4) are in series between the bases of transistors (6, 7), and in parallel with a capacitor (16). A resistor (2) connected to the supply voltage (UB) is connected to the junction point between the capacitor (16) and the diode (3).

Description

Control circuit with positive and negative

Output current and downstream push-pull power output stages The The invention relates to a control circuit specified in the preamble of claim 1.

There are vertical deflection circuits for television receivers known that from an integrated amplifier circuit with a subsequent current amplifier stage exist, to which two power transistors connected as push-pull amplifiers with single-ended output are turned on.

The output stage transistors are controlled according to the Method known from LF amplifier technology (Funkschau No. 11/77, page 481) a stable base-emitter bias voltage by means of a current flowing through two diodes for the controlled transistor and to avoid a takeover distortion.

The control is still supported in the known circuit by one between the output of the power amplifier and the base of the controlled Transistor-switched bootstrap capacitor.

However, this circuit has the disadvantage that a large driving power must be applied for the output stage, which integrated the used as a driver Circuit heavily loaded, and that special measures to dissipate the harmful heat of the IC must be taken, for example with the help of a Cooling plate. During the conduction phase of the second transistor of the output stage flows due to between the supply voltage and the output gear of the IC If there is a high voltage drop, a high current in the IC in addition to the drive current into the base of the transistor.

The invention is based on the object of providing a control circuit create, with a simple structure, a low power consumption and a has reduced reverse current to the IC.

This object is achieved according to the invention by what is specified in claim 1 Invention solved.

Further developments of the invention are specified in the subclaims.

The invention has the particular advantage that the driver performance and the IC power loss is reduced and the cooling measures (e.g. cooling plates) for the IC can be saved.

An embodiment of the invention is shown in the drawing and described in more detail below.

FIG. 1 shows, schematically represented, a known circuit in comparison to a circuit according to the invention shown in FIG. 2, FIG 3a to 3g and FIGS. 4a to 4f are diagrams to explain the invention.

In Figure 1, only those circuit parts of a known circuit are shown, which is important for a comparison with the circuit according to the invention to have.

The IC 5 contains the vertical deflection circuit with oscillator, Sawtooth generator, vertical deflection preamplifier and power amplifier. To the IC 5 is one consisting of the series connection of two series resistors 1, 2 and two diodes 3, 4 Control network switched, followed by a push-pull power output stage, the consists of the complementary transistors 6 and 7. With UB is the supply voltage source designated. Between the series resistors 1 and 2 and the common emitter point 12, a bootstrap capacitor 8 is connected. At point 12 are the vertical deflection stage 9 and herewith a coupling capacitor 10 and a measuring resistor 11 connected in series.

The sawtooth-shaped one located at the output of the integrated circuits 5 Voltage is at 14 and the amplified identical vertical deflection voltage is at 15 designated.

Between the coupling capacitor 10 and the measuring resistor 11 is a Measurement voltage for negative feedback (not shown) for IC 5 is tapped. The exit of the IC 5 is denoted by 13.

A current flows through the diodes 3 and 4, which through the series resistors 1 and 2 is determined. Control is also supported by output 12 of the push-pull output amplifier formed by the complementary transistors 6, 7 and the base of transistor 6.

In the bases of transistors 6 and 7 of the push-pull output amplifier a current corresponding to the sawtooth voltage 14 is fed in from IC 5, which is synchronous with the vertical frequency, the two transistors 6 and 7 operated in push-pull. Through the series resistors 1 and 2 and the diodes 3 and 4 flows a current that is on the diodes 3 and 4 have a voltage drop causes, so that the base of the transistor 6 always by an amount 2 UF (where with U denotes the forward voltage) with respect to the base of the transistor 7 is biased is. The driver current for the (controlled) transistor 6 can (for the positive Half-wave) must only be as large as the maximum determined by the series resistors.

In this known circuit, the resistors 1 and 2 must be very be low-resistance so that a sufficient base current can flow. This is necessary in order to achieve a continuous voltage curve at the common emitter point 12. Without this measure, there would be a jump in voltage, which is a discontinuous deflection of the electron beam in the center of the screen (so-called pinch folds).

During the conducting phase of the transistor 7, the bootstrap capacitor 8 charged via series resistor 1 and UB, (i.e. when transistor 7 conducts, there is therefore a high harmful cross current). During the conduction phase of the transistor 6 (blocking phase of transistor 7), the bootstrap capacitor 8 discharges via the Series resistor 2 and transistor 6 (via circuit parts 12, 9, 10, 11, ground) and thereby supplies it with an additional base current. So it has to be a big one Driver power can be applied to the output stage that is used as a driver integrated circuit 5 is heavily loaded, so that the high power loss, e.g. with the help of a cooling plate. During the lead phase of the Transistor 7 flows due to the high voltage drop between the supply voltage UB and the output 13 of the IC 5 a high current (from UB via the circuit elements 1, 2, 3, 4) in addition to the control current of the transistor 7 through the diodes 3 and 4 and the transistor current of transistor 7.

This circuit is based on the preamplifier in IC 5 to control the transistor 6, a negative current steadily decreasing towards zero necessary.

This current flows with a larger value when the transistor is blocked 6 and the modulation of the transistor 7 as a preload current in the IC 5 and results a significant increase in power loss of the control circuit.

The course of the resistors 1 and 2 and the diodes 3 and 4?; W s, ow, ieddurgh capacitor 16 and the 1, Lleilc (eil StrLlmr driver circuit and the base currents of the transistors 6 and 7 can be seen from FIGS. 3a to 3g.

In these figures, i denotes the current mentioned, t or

t1 to t6 the temporal progression, TH the downward travel time and Tr the downward travel time and 0 the zero line.

In the case of positive control, resistors 1 and 2 must be dimensioned in this way be that enough drive current is applied to the transistor 6, since this the maximum base current is needed. This is shown at time t1 in FIG. 3e. The base current of the transistor 6 flows from the capacitor 8 via the resistor 2, as can be seen in FIGS. 3b and 3g.

With negative control, ie control of the transistor 7, between the times shortly before t3 and t4, current flows from the base of this transistor -Figure 3fin the driver circuit 5 -Figure 3d-. At the same time, the driver circuit must 5 also the current through the resistors 1 -Figur 3a- and 2 -Figur 3b- as well through the diodes 3 and 4 -Figur 3c- record. The outward run is ended at time t4. Here the current through the elements listed above has its maximum value. It The largest charging current also flows into the bootstrap capacitor 8 - Figure 3g- There the circuit of Figure 1 is already described in detail, need those Circuit parts and functions of Figure 2 that correspond to those of Figure 1, not to be explained again, so that it is sufficient to only use the same parts to be provided with the same reference numerals.

A major difference between that in Figure 2 to that in Figure 1 is that the existing in Figure 1 bootstrap capacitor 8 and the series resistor 2 are omitted. Instead, it is parallel to the two Diodes 3 and 4 are connected to a charging capacitor 16. In addition, the resistance is 2 high resistance dimensioned.

While the transistor 7 conducts, the voltage drop across the in this circuit high resistance 2 UR - UB - 2 UF - UAIC.

UR = voltage drop across resistor 2, UB = supply voltage, UF = Voltage during the flow period, UAIC = output voltage of the IC 5). The through The current caused by this voltage drop charges during the conduction phase of the transistor 7 (via the circuit parts UB, 2, IC 5) on the charging capacitor 16.

During the conducting phase of transistor 6, transistor 7 is blocked. The IC 5 supplies the voltage control, while the resistor 2 supplies the base current is delivered.

Since the resistor 2 has a high resistance, the current is sufficient to drive the Transistor 6 does not turn off, so that the charging capacitor 16 provided for this purpose, the remaining Electricity supplies.

The voltage curve (sawtooth-shaped voltage 14) at the output of the IC 5 is about the same (vertical deflection voltage 15) as at the output, at the common Emitter connection 12. Only the current flow through the transistors 6 and 7 is approximately p times the control signal, represented by the sawtooth voltage 14, where powder is the current gain factor of the transistors.

While in the circuit of Figure 1 from that contained in IC 5 Preamplifier for modulating the transistor 6 a negative steadily decreasing towards zero Current is required, which is greater when the transistor 6 and is blocked Control of the transistor 7 flows as a preload current in the IC i and a substantial There is an increase in power loss of the control circuit, however, is in the control circuit according to Figure 2, the maximum current when the transistor 7 is driven only about Half.

This results from the fact that the control circuit when controlled of the transistor 6 is able to deliver a negative current. Hence the losses in the control circuit compared to the circuit shown in Figure 1 is essential degraded.

The course of the individual currents is again shown in FIGS. 4a to 4f shown schematically. The prerequisite for this control of the output stages is that the driver circuit can deliver current as well as absorb current.

The outward run begins at tl. With positive control, part flows of the base current for the transistor 6 via the resistor 2 -Figur 4a- a part from the charged capacitor 16 -Figur 4c- and via this capacitor from the Driver circuit 5 - Figure 4f. At time t2, the current that flows from the driver circuit 5 is supplied to zero and from this point in time the driver circuit 5 takes current on. The base current - Figure 4d- has now become smaller and is only generated via resistance 2 -Figur 4a- delivered. The current consumed by the driver circuit 5 flows via the resistor 2 and via the diodes 3 and 4 -Figur 4b-. Just before t3 starts the transistor 7 to conduct. Shortly after t3, the transistor 6 stops conducting. This is necessary to avoid takeover bias. By the stream that through the diodes 3 and 4 flows - Figure 4b- there is a voltage drop across them, which discharges the capacitor 16 -Figur 4c- via the resistor 2 -Figur 4a-. At the time t4 flows from the transistor 7 the maximum base current figure 4ein the driver circuit. The same applies to diodes 3 and 4, resistor 2 and the capacitor 16.

A comparison of Figures 3 and 4 shows that in Figure 3d the current in the driver circuit is greater than the current in Figure 4f.

The heating of the driver circuit according to FIG. 2 is less than in the circuit of Figure 1, so that in the circuit shown in Figure 2 on a heat sink to dissipate the heat loss from the driver circuit can be dispensed with can.

This is because the driver circuit is both supplying current as well as record. Therefore, the losses in the drive circuit are opposite the circuit shown in Figure 1 is significantly reduced.

In the exemplary embodiment there are vertical deflection circuits with ICs described, but the invention is also for all amplifier circuits with downstream Power levels applicable.

3 sheets of drawings

Claims (4)

Control circuit with positive and negative output current and downstream push-pull power output stages, especially for vertical deflection circuits of television receivers, characterized in that the output of the control circuit (Vertical deflection circuit 5) directly to the base of a transistor (7) of the push-pull power output stage (6,7) is connected, and between the base connections of the transistors (6, 7) the push-pull power output stage has two diodes (3, 4) in series and in parallel a charging capacitor (16) are connected, and at the connection between the Charging capacitor (16) and the diode (3) a resistor (2) on the supply voltage (UB) lies. 2. Circuit according to claim 1, characterized in that the control circuit (Vertical deflection circuit 5) is an IC circuit. 3. Modification of the circuit according to claim 1 or 2, characterized in that that instead of the diodes (3, 4) a resistor is provided. 4. Circuit according to one of the preceding claims, characterized by using it for power amplifiers to amplify non-sawtooth signals.