DE2347192A1 - Control voltage generation cct. - designed for picture IF amplifier and for interference pulses suppression from video signal - Google Patents

Abstract

The base of a first transistor is connected to an input for the video signal. Its collector is connected to an output for the reversed polarity video signal, and through a resistor to frame. Its emitter is, together with a second transistor emitter, connected through a resistor to a supply voltage source. The second transistor base is connected to the tapping of a resistive voltage divider between the voltage source and frame, and through a capacitor to frame. Its collector is connected to an output for the control voltage and through a capacitor in parallel with a resistor to frame.

Description

SIEMENS AKTIENGESELLSCHAFT Manchen 2, 19th SER 1973

Berlin and Munich Wittelsbacherplatz 2

73/1184

Circuit arrangement for generating control voltage for the image intermediate frequency amplifier and for glitching the video signal in a television receiver

The invention relates to a circuit arrangement for generating control voltage for the image intermediate frequency amplifier and for the elimination of interference pulses in the video signal in a television receiver.

In complex television receiving circuits, a control voltage for the image intermediate frequency amplifier can be used as a result produce that the amplitude of the video signal is determined with the aid of sampling pulses. For example this is in the magazine "Funkschau" 1972 issue 4 pages 105 bis described. Interference pulses in the video signal can be filtered out with the help of selective circles, whereby the pulse separation stage, which separates the sync signals from the video signal, is blocked for the duration of such disturbances. This also means however, a considerable effort that is not justified in simpler devices. Especially with portable television receivers the effort should be kept as small as possible.

The present invention is based on the object of a Specify circuit arrangement, the two functions mentioned, the production of the control voltage and the interference clearance combined as much as possible and with as little effort as possible.

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To solve this problem v. ^r ir <?. at. a circuit arrangement of the type mentioned according to the invention that the base of a first transistor is connected to an input for the video signal, that the collector is at an output for the video signal of opposite polarity and leads via an ohmic resistor to the reference potential that the emitter together with the emitter of a second transistor of the same type leads via an ohmic resistor to an operating voltage source, that the base of the second transistor is at the divider point of an ohmic voltage divider connected between the operating voltage source and the reference potential and is connected to the reference potential via the capacitor, that finally the collector of the second transistor leads to the reference potential via a capacitor and parallel thereto via an ohmic resistor and is connected to an output for a control voltage.

Such a circuit arrangement according to the invention not only fulfills the two required functions of generating the control voltage for the image intermediate frequency amplifier and the interference pulse liberation of the video signal, but also requires only an extremely small amount of circuitry for this.

The invention will be explained in more detail using an exemplary embodiment shown in the drawing. A circuit arrangement according to the invention is shown in FIG. 1. Figures 2 and 3 show the Course of the video signal at the input or at the output of the circuit arrangement according to FIG. 1.

An input 1 with an input video signal U _e is with

connected to the base of a transistor 5 of the pnp type. The collector of this transistor 5 leads to an output

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4 with an output video signal U and via an ohmic resistor 7 to the reference potential. The emitter of the transistor 5, together with the emitter of a transistor, also of the pnp type, is connected via an ohmic resistor 6 to a source 2 for an operating voltage U ^. The base of the transistor 8 is connected to the operating voltage source 2 via an ohmic resistor 11 and to the reference potential via an ohmic resistor 12, a capacitor 13 being connected in parallel with the ohmic resistor 12. The ohmic resistors 11 and 12 form a voltage divider, to the divider point of which the base of the transistor 8 is connected. The collector of the transistor 8 leads to an output 3 for a control voltage U _re ". In addition, the collector is connected to the reference potential via an ohmic resistor 9 and, in parallel, via a capacitor 10.

In FIG. 2, the time course of the input video signal U is shown and a target voltage is shown in dashed lines U -, -, drawn. Fig. 3 shows the temporal Course of the output video signal U.

The video signal from the video rectifier is fed in with negative polarity and arrives at terminal 1 to the base of the transistor 5. At the base of the transistor 8 there is a DC voltage which, with the aid of the Voltage divider 11,12 is set. Assuming that the base of the transistor 5 only during the duration of the pulse peaks of the sync signals of the video signal is more positive than the base of the transistor 8, then means this is that the transistor 5 is blocked only during the sync pulse duration, while the transistor 8 is conductive during this time. During the conductive phase of the transistor 8, a appears at the resistor 9 Voltage drop, the mean value of which with the help of the condenser

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Sators 10 is formed and aer as a control voltage at the output 3 is used for the image intermediate frequency amplifier.

Provided that an increase in the control voltage U decreases the output amplitude reg

should result at the output of the intermediate frame rate amplifier, must with increasing video signal on Input 1 - during the sync pulse duration - a larger one Current flow through the transistor 8 and, as a result, a larger control voltage arise, the magnification of the video signal. U counteracts. This until

e
A state of equilibrium has been established and the amplitude of the sync pulse peaks is equal to the setpoint given at the base of transistor 8. Since the transistor 5 is blocked during the sync pulses, the output level of the video signal U during the sync pulse duration is 0. During the rest of the time, the video signal U is amplified according to the resistance ratio of the ohmic resistors 6 and 7

at the ohmic resistor 7 and thus at the output 4 with reversed polarity. If now, for example, glitches occur in the video area that extend over or up to the sync pulse peaks, then during this Time also the transistor 5 is blocked, so that the glitches at the output 4 do not go further than up to the value

0 can be enough. This means that the coupling capacitor is charged avoided in the further connected amplitude filter, so that the amplitude filter in the event of interference pulses cannot be blocked.

For the control voltage output 3, interference pulses mean an increase in the control voltage, but it falls if the time constant of the capacitor 10 and the ohmic resistor 9 is sufficiently large, this does not matter.

1 claim
3 figures

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Claims (5)

Claim Circuit arrangement for generating active voltage for the Image intermediate frequency amplifier and for the interference pulse liberation of the video signal in a television receiver, thereby characterized in that the base of a first Transistor (5) is connected to an input (1) for the video signal (U) that the collector at one Output 4 for the video signal (U) of reversed polarity and via an ohmic resistor (7) leads to the reference potential that the emitter together with the emitter a second transistor (8) of the same type via a Ohmic resistance (6) leads to an operating voltage source (2) that the base of the second transistor (8) at the dividing point an ohmic voltage divider connected between the operating voltage source (2) and the reference potential (11, 12) is and via a capacitor (13) with the Reference potential is connected that finally the collector of the second transistor (8) via a capacitor (1O) and in parallel via an ohmic resistor (9) leads to the reference potential and with an output (3) for a control voltage (U) is connected. VPA 9/110/2058 RH / REU 5 09813/0654 Blank page