DE4238615C1 - Generating line flyback pulses for display tube - using operational amplifier circuit with input from sawtooth wave signal generator controlling amplitude and frequency - Google Patents

Abstract

The line flyback pulses (UBL) are generated by a circuit having an operational amplifier (OP2) receiving a voltage (UO at the inverted input. This is determined by a voltage divider (R4,R5), one of the resistors (R5) being variable to vary the mark to space of the cycle, while holding the frequency and amplitude constant. The other input receives a sawtooth voltage signal (US) and this connects to a transistor (T3). A diode (D) also connects to the input. The sawtooth voltage provides a frequency and amplitude adjustable signal to control the flyback pulses. USE/ADVANTAGE - TV receivers and VDU's. Provides pulses independent of amplitude and frequency.

Description

The invention relates to a method and a circuit arrangement to generate a return pulse for the rewind blanking of an image display device, wherein the return pulse is derived from a sawtooth voltage is that by charging a capacitor and discharge is generated and a frequency and amplitude independent Has a response time.

A generic circuit arrangement for generation a flyback pulse that comes from a sawtooth voltage is derived is known from DE 25 33 599 B2. This known circuit arrangement contains a capacitor, that by means of a charging current source and a Discharge current source periodically charged and discharged becomes. The voltage of the capacitor increases due to the charging current linearly until it reaches a first reference voltage reached, causing the rapid discharge of the Capacitor put the discharge current source into operation becomes. Now the capacitor voltage reaches one second reference voltage, which is less than the first, the charging process starts again. The first reference voltage  therefore corresponds to the upper reversal point and the second reference voltage the lower reversal point the sawtooth voltage. The synchronization of the Charging and discharging is carried out by externally supplied Sync pulses. The amplitude of the so generated Sawtooth voltage is independent of the frequency the synchronizing pulses controlling the circuit arrangement. A circuit arrangement that also works according to this principle is from patent application P 42 34 735 known, with the addition also a setting of Amplitude of the sawtooth voltage is possible. At least for the second known circuit arrangement it is from Advantage if the sawtooth voltages generated one of the constant return duration independent of the frequency, ie has a constant discharge time of the capacitor.

Such circuits are used, for example, for control purposes of vertical amplifiers in multi-standard TV sets and viewing devices used by computers, one pulse starting at the start of the discharge process mainly required for blanking out the picture tube becomes.

Blanking circuits serve to inject the electron beam a picture tube during the return times of the beam hide or feel. If the electron beam not suppressed during its return movement will appear on the screen of the picture tube so-called return lines. In the case of vertical rewind  are white or colored, diagonally across the Grid lines. To avoid such lines, a return suppression circuit is usually used.

According to DE 25 35 599 B2 mentioned above, with the circuit arrangement for generating the sawtooth voltage generates a pulse that is used for blanking and which in turn is used to control the distraction shorter return pulse is derived. These known circuit arrangement has the disadvantage on that with a variation in the frequency of the sync pulses the discharge time of the capacitor is constant would remain and thus the proportionality of the Reverse blanking voltage not guaranteed for the period is.

In the prior art, this proportionality becomes apparent ensures that both the loading and the Discharge current changed proportionally with frequency becomes. Among other things, this has the disadvantage that with one such a sawtooth-shaped voltage curve the immediate Control of special  Power operational amplifiers developed for vertical deflection purposes with a so-called fly-back generator not possible. Put such operational amplifiers a control voltage to trigger the fly-back generator ahead at which the fall time is essential is smaller than the actual return process in the deflection circuit or as the duration of the required Rewind blanking.

The object of the invention is a method to generate a return pulse from which to specify one of a frequency adjustable and amplitude adjustable Sawtooth generator generated sawtooth voltage is derived, this sawtooth generator a capacitor to generate the sawtooth voltage charges and discharges and the discharge time, i.e. the return time of the sawtooth-shaped voltage curve, frequency and amplitude-independent of the set amplitude the sawtooth voltage is.

This task is characterized by the characteristics of claim 1 solved. Then there is the solution in that first a frequency-independent and amplitude-proportional voltage threshold is generated, the between the upper and lower reversal point of the sawtooth Voltage curve lies. Then will the sawtooth-shaped voltage curve with respect to its reference voltage around a frequency and amplitude proportional Voltage value in the direction of their change from Charging point marking the discharge state postponed. The return pulse results from the fact that the time at which the sawtooth voltage begins to reverse their leading edge is determined while their  Trailing edge is formed when the shifted sawtooth curve the voltage threshold during their run reached.

The above task is also characterized by the Features of claim 2 solved. After that not the sawtooth tension is shifted, but the frequency-independent and amplitude-proportional voltage threshold is a frequency and amplitude proportional Voltage value lowered. The leading edge the return pulse is also at the beginning the return of the sawtooth voltage generated while the trailing edge is then formed in this solution becomes, if the sawtooth curve the shifted voltage threshold intersects.

An advantageous circuit arrangement for implementation of the method according to the invention is the claims 3 to 8.

In the following the invention in connection with the Drawings are illustrated and explained. Show it

Fig. 1 is a schematic representation of the generation of a sawtooth voltage with independent from the frequency amplitude and return time,

Fig. 2 voltage diagrams for explaining the generation of a flyback pulse,

Fig. 3 shows a circuit arrangement for explaining the voltage diagrams of Fig. 2,

Fig. 4 shows a further circuit arrangement for explaining the voltage diagrams of Fig. 2,

Fig. 5 shows a circuit arrangement for performing the method according to the invention and

Fig. 6 shows a further circuit arrangement for performing the method according to the invention.

To generate the return pulse according to the invention, the invention is based on a sawtooth voltage which has a frequency-independent amplitude. Such a sawtooth voltage is generated by a sawtooth generator, as is shown in principle in FIG. 1 and is known, for example, from the already mentioned patent application P 42 34 735.

According to this Fig. 1, a capacitor C is moved up or via a switch S, depending on the switch position discharged. In the drawn upper position of the switch S, the capacitor C is charged via a transistor T 1 and a resistor R 1 by a charging current I _L until a predetermined voltage value U 1 is reached. Then the switch S is flipped and the capacitor C discharged until a second predetermined voltage value U₂ is reached, a discharge current I _E flowing through a transistor T₂ and a resistor R₂ to ground. After the discharge process has ended, the switch S returns to the upper position. This creates a sawtooth-shaped voltage curve with an amplitude that corresponds to the difference between the two voltage thresholds U 1 and U 2. By varying the control voltage U _F applied to the base electrode of the transistor T 1, the charging current I _L and thus the frequency or the period duration T _P can be influenced without changing the ramp-down time T _R , which by means of a Electrode of the transistor T₂ applied voltage U _{E can be set} independently of frequency. With a change in the amplitude of the sawtooth voltage, that is, the change in the voltage threshold U 1 and U 2, a change in the discharge current I _E can be coupled via the voltage U _E such that the ramp-down time T _R is independent of the amplitude set.

The circuit 1 including the switch S also generates a pulse voltage U _P of the duration of the ramp-down time T _R. This pulse voltage U _{P also} represents the voltage that causes the switch S to switch. The operational amplifier OP1, which is connected as a voltage follower, is intended to prevent a load, that is to say, for example, a linearity influence on the voltage profile at the capacitor C by downstream circuit parts.

Fig. 2a shows the sawtooth-shaped voltage curve U _S with respect to the return flow with the time period T _R and a portion of the subsequent trace time. The voltage threshold U₁ and U₂ forms the upper and lower reversal point of the sawtooth voltage curve U _S. Furthermore, a third voltage threshold U₃ is shown, which is located above the voltage threshold U₂ by a voltage amount U _D. If one now performs as shown in FIG. 3, the sawtooth voltage U _S the non-inverting input of operational amplifier OP2 to and closes the third threshold voltage U₃ at the inverting input of this operational amplifier, so a negative pulse U _OP arises at the output of the period T₁ in accordance with of Fig. 2b. This results from the fact that a low level is only output at the output of the operational amplifier OP2 if the voltage level at the non-inverting input is lower than that at the inverting input.

This pulse U _OP alone cannot be used for blanking out the return, since it does not start at the same time as the return (upper reversal point) of the sawtooth voltage U _S. For this purpose, for example, as shown in Fig. 4, the non-inverting input of the operational amplifier OP2 via a resistor R₃ and a diode D, the pulse voltage U _{P shown in} FIG. 2c can also be supplied, so that at the output of said operational amplifier Sets the voltage pulse U _BL according to FIG. 2d. Since this pulse U _{P is} at low potential, there is a voltage level at the non-inverting input of the operational amplifier OP2 during the entire return period, which is less than the voltage threshold U₃. The missing time difference between the leading edge of the pulse U _OP and the point in time at which the capacitor is discharged is thus filled up by means of the pulse U _P.

One would now an extremely short payback time, therefore T _R ~ assume 0, the voltage value U _D for the value of the amplitude (U₁-U₂) would result in a strictly proportional to the period duration of the sawtooth voltage U _S time duration of the pulse U _BL at a constant ratio. However, because of the finite and constant return time T _R , which is not proportional to the period, this is not the case here.

Strict proportionality results when the following relationship exists:

U _D : (U₁ - U₂) = (T _BL - T _R ): (T _P - T _R ),

where T _{P represents} the period of the sawtooth voltage. Solving this equation according to the voltage value U _D and simplifying the equation on the basis of the return time T _R that is negligible for the period T _P results in:

Since the pulse duration T _{BL should be} proportional to the period T _P , the voltage value U _D * is composed of a constant voltage value U _D1 and a variable voltage value U _D2 . The voltage value U _D1 is proportional to the quotient T _BL / T _{P of} the time period T _{BL of} the pulse U _BL and the period T _P , while the voltage value U _{D2 is} proportional to the quotient T _R / T _P from the constant flyback period T _R and Period T _P is.

The voltage value U _D2 compensates for the influence of the constancy of the ramp-down time T _R on the proportionality from T _BL to T _P. With the other value U _D1 , it is therefore possible to set the ratio of blanking time T _BL to period T _P without having to change the voltage value U _D2 at the same time, provided that the ramp-down time T _R always remains shorter than the blanking time T _BL .

Fig. 5 shows a circuit arrangement for the generation of the retrace pulse U _BL of the invention. For this purpose, the voltage U _{D1 is} applied to an operational amplifier OP2 at its inverting input, which voltage is generated by means of two resistors R₄ and R₅ forming a voltage divider. The fact that this voltage divider connects the voltage levels U₁ and U₂ and the resistor R₅ is adjustable, the desired ratio of blanking time T _BL to the period T _P can be set.

At the non-inverting input of the operational amplifier OP2, the sawtooth voltage U _{S is} applied via a resistor R₃. Furthermore, this input is connected via an emitter-collector path of a transistor T₃ and a resistor R₆ to a voltage source U _CC . At the base electrode of this transistor T₃ is the control voltage U _F , which also controls the charging current I _L and thus the frequency according to FIG. 1. Thus, the resistor R₃ is flowed through by an impressed current, which thereby generates the frequency and amplitude-proportional voltage drop U _D2 . This voltage drop U _D2 is thus superimposed on the sawtooth-shaped voltage curve U _S. Finally, in order to supply the pulse U _P, a diode D is connected to the non-inverting input of the operational amplifier OP2 in order to achieve the effect already explained in connection with FIG. 4. A return pulse U _BL is therefore available at the output of the operational amplifier OP2, the period T _{BL of} which is proportional to the period U _S.

Fig. 6 shows a further circuit arrangement for the generation of the retrace pulse U _BL of the invention. This circuit arrangement differs from that according to FIG. 5 in that the voltage value U _{D2 is} not generated at the non-inverting input of the operational amplifier, but is fed to the inverting input in addition to the voltage value U _D1 . The result of this is that the sawtooth voltage U _S is not shifted, but rather the voltage threshold U _D1 is lowered by the amount of the voltage value U _D2 .

The realization is based on Fig. 6 via an npn transistor T₃ ', base electrode, the control voltage U _F at its' is applied, which is formed by inverting the control voltage U _F. The series circuit from the emitter-collector path of this transistor T₃ 'and a resistor R₆' connects the inverting input of the operational amplifier OP2 with the reference potential of the circuit arrangement. A resistor R₃ 'also connected to the inverting input is therefore flowed through by an impressed current, whereby the frequency-proportional voltage value U _{D2 is} generated at this resistor R₃'.

Between the resistor R₃ 'and the connection node of the voltage divider R₄ / R₅ is a voltage follower switched operational amplifier OP3 switched. This  can be omitted if the resistance value of the Resistance R₃ 'is 1-2 orders of magnitude larger than that of resistance R₅.

Claims (8)

1. Method for generating a return pulse (U _BL ) for the return blanking of an image display device from a sawtooth voltage (U _S ) generated by means of a capacitor by charging and discharging, which has a frequency and amplitude-independent return period (T _R ), characterized by the following features:

• a) A frequency-independent and amplitude-proportional voltage threshold (U _D1 ) is generated, which lies between the upper and lower reversal point (U₁, U₂) of the sawtooth-shaped voltage curve (U _S ),
• b) a voltage value (U _D2 ) proportional to frequency and amplitude is also generated,
• c) the sawtooth-shaped voltage curve (U _S ) is shifted with respect to its reference voltage by the voltage value (U _D2 ) generated according to feature b) in the direction of the curve point marking its change from the charging to the discharging state and
• d) at the time of the beginning of the return of the sawtooth voltage (U _S ), the leading edge of the return pulse (U _BL ) is generated, during the trailing edge of which is formed when the sawtooth curve (U _S ) shifted according to feature c) during its run-up the according to feature a) defined voltage threshold (U _D1 ) intersects.

2. Method for generating a return pulse (U _BL ) for the return blanking of an image display device from a sawtooth voltage (U _S ) generated by means of a capacitor by charging and discharging, which has a frequency and amplitude-independent return duration (T _R ), characterized by the following features:

• a) A frequency-independent and amplitude-proportional voltage threshold (U _D1 ) is generated, which lies between the upper and lower reversal point (U₁, U₂) of the sawtooth-shaped voltage curve (U _S ),
• b) a voltage and amplitude-proportional voltage value (U _D2 ) is also generated,
• c) the voltage threshold (U _D1 ) generated according to feature a) is reduced by the voltage value (U _D2 ) generated according to feature b) and
• d) at the time of the beginning of the return of the sawtooth voltage (U _S ), the leading edge of the return pulse (U _BL ) is generated, during the trailing edge of which is formed when the sawtooth curve (U _S ) during its run-up has shifted the voltage threshold according to feature c) ( U _D1 ) cuts.

3. Circuit arrangement for carrying out the method according to claim 1, wherein the capacitor is part of an oscillator circuit which generates a square-wave pulse (U _P ) corresponding to the flyback period of the sawtooth voltage (U _S ), characterized by the following features:

• a) the rectangular pulse (U _P ) has a smaller voltage value than the voltage threshold (U _D1 ),
• b) a circuit (OP2) for comparing the amplitude with a first and second input is provided,
• c) the voltage threshold (U _D1 ) is fed to the first input of the circuit,
• d) the voltage of the shifted sawtooth curve (U _S ) is applied to the second input of the circuit and
• e) finally, the square-wave pulse (U _P ) is also fed to the second input of the circuit via a rectifier element.

4. Circuit arrangement according to claim 3, characterized in that the displacement of the sawtooth curve is carried out by means of a resistor (R₃), to which the sawtooth voltage (U _S ) is supplied on the one hand and which is flowed through by a frequency and amplitude proportional current. 5. Circuit arrangement for carrying out the method according to claim 2, wherein the capacitor is part of an oscillator circuit which generates a square-wave pulse (U _P ) corresponding to the flyback period of the sawtooth voltage (U _S ), characterized by the following features:

• a) the rectangular pulse (U _P ) has a smaller voltage value than the voltage threshold (U _D1 ),
• b) a circuit (OP2) for comparing the amplitude with a first and second input is provided,
• c) the shifted voltage threshold (U _D1 ) is fed to the shifted first input of the circuit,
• d) the voltage of the sawtooth curve (U _S ) is applied to the second input of the circuit and
• e) finally, the square-wave pulse (U _P ) is also fed to the second input of the circuit via a rectifier element.

6. Circuit arrangement according to claim 5, characterized in that the displacement of the voltage threshold (U _D1 ) by means of a resistor (R₃ '), to which on the one hand the voltage threshold (U _D1 ) is supplied and on the other hand is flowed through by a frequency and amplitude proportional current. 7. Circuit arrangement according to one of claims 3 to 6, characterized in that the voltage threshold (U _D1 ) is generated by means of an adjustable voltage divider with two resistors (R₄, R₅), on the one hand from a voltage value corresponding to the upper reversal point and on the other hand the lower reversal point (U₁, U₂) is fed. 8. Circuit arrangement according to one of claims 3 to 7, characterized in that the circuit for amplitude comparison represents an operational amplifier (OP2).