HU177560B - Method and arrangement for generating saw-tooth signal - Google Patents

Abstract

The generator which produces sawtooth colour difference signals, required no polarity reversal for the SECAM R-Y signal and no sequential changing over between the R-Y and B-Y signals. A rectangular wave signal (a) -- of half the horizontal frequency is applied to the bases of two complementary transistors connected together at their collectors and is converted into a signal with positive and negative ramps. This ramp signal is clamped during the horizontal blanking period using an FET switch connected between the collectors and zero potential.

Description

patentee:

Róbert Bosch GmbH,

Stuttgart,

Federal Republic of Germany

A method and a switching arrangement for generating a wind signal

The present invention relates to a method and a switching arrangement for producing a saw in the color video signal of a secam color television system for an identification pulse engulfed during a vertical extinction.

"Technische Mitteilungen RFZ" Issue 13, 3/1969 is known. 82-94. page 18, and in particular on page 91 of page 91 and page 92

Fig. 22 shows that the video signal encoded in the secam system receives identification signals during the vertical extinction. The identification signal consists of row frequency saws, which are added to the color channel signals (R-Y) and (B-Y) generated by the color video signal source into a color channel of the secam encoder. In order to change the polarity of the color difference signal (R-Y) and to sequentially change the color difference signals (R-Y) and (B-Y), a saw-shaped pulse sequence is provided to the connected frequency modulator, whereby the polarity of each saw teeth changes from one row to the next.

It is an object of the present invention to provide a method and switching arrangement as defined in the introduction, in which the polarity change and the sequential switching of color transition signals requiring complex construction can be omitted.

The object of the present invention is achieved by a method of generating the same frequency, positive and negative, signals from a half-frequency meander-shaped signal using a function generator, which is drawn to a constant potential by means of a controlled switch during the horizontal extinction.

The advantage of the method according to the invention is that the signal containing the identification pulse can be produced in a simple manner, for example, when assigning the video signal encoded in the secam system to the black-and-white video signal for the resolution of the black and white video signal in the secam decoders. do not fall out of sync.

The method according to the invention is also implemented by a circuit arrangement according to the invention, which comprises a first current generator and a second parallel current generator with parallel input, the input of which is led by a half-row meander-shaped signal, and a capacitor having one of them. the output of the two current generators is connected to a constant voltage point, preferably a ground potential, and a switching transistor whose controlled switch section is connected in parallel with the capacitor, and a series frequency pulse is directed to its control electrode.

According to a preferred embodiment of the coupling arrangement according to the invention, the first current generator comprises an npn transistor, the emitter of which is connected to a negative voltage via a first resistor and its base via a second resistor, and its base is further coupled by a third, fourth and fifth resistor serial circuit. connected to voltage.

According to a further embodiment of the circuit arrangement according to the invention, the second current generator consists of a pnp transistor whose emitter is connected to a positive voltage at a sixth resistor and its base is connected to a positive voltage via a fifth resistor, and its base is also connected to a negative voltage via a second, third and fourth resistor serial circuit. is switched on.

The connection between the third and fourth resistor of the serial circuit is pointed to the half-frequency meander-shaped signal.

According to a preferred embodiment of the coupling arrangement according to the invention, it comprises an integrating circuit with a differential amplifier, the inverting input of which is led through the capacitor to the output of the differential amplifier, on the other hand, is connected via a resistor to the input terminal, which has a meander-shaped signal at half-frequency of the input terminal, non-inverting. input is connected to a constant voltage point, and there is a switching transistor whose controlled switch section is connected between the inverter input of the differential amplifier and the constant voltage point, the control electrode is controlled by line frequency pulses.

In this latter embodiment, the half-line meander-shaped signal is guided to the resistor via a coupling capacitor, and a coupling of an adjustable voltage divider is connected to the coupling capacitor and the connection point of the resistor, which is connected to a voltage divider negative and positive voltage.

The switching section of the switching transistors used in the above embodiments is preferably a source-drain section of a spatially controlled transistor whose gate forms the control electrode.

The invention will now be described in more detail with reference to the exemplary embodiments shown in the accompanying drawings, where

Fig. 1 shows one embodiment of a circuit arrangement for carrying out the method according to the invention, a

Figure 2 shows a further embodiment of a circuit arrangement for carrying out the method of the present invention;

Figure 3 shows the signal shapes for explaining the operation of the two layouts according to the two embodiments.

Fig. 1 shows a rectangular signal at terminal I having a frequency equal to half the line frequency in one embodiment. 2 is coupled to the inputs of two complementary current generators via a coupling capacitor. while u is composed of another 4 pnp transistors. In the current generator constructed from the .3 npn transistor, the emitter is connected to the negative voltage at terminal 6 via the first resistor 5 The base of the 3 npn transistor is provided by a second resistor 7 and a third, fourth and fifth serial switching of resistors 8.9 and 10. connected to a negative voltage point at terminal 6 and a positive voltage point at terminal II. In the current generator constructed with the transistor 4, the emitter is connected to the positive voltage at terminal II via the sixth resistor 12. The base of the pnp transistor 4 is connected to a branch of a voltage divider formed by a serial connection of a second resistor 10 and a second, third and fourth resistor 7 and 8 respectively. This voltage divider is connected to the positive voltage at terminal 11 and negative voltage at terminal 6. The collector of the 3 npn transistor and the transistor 4 are connected and form the output of the two current generators (terminal 13). The output of the current generators built with the 3 npn transistor and the transistor 4 is connected to a capacitor 14, the other of which is connected to ground potential (terminal 15).

With the capacitor A14, the source-drain section of a space-controlled transistor 16 is coupled in parallel, which receives a quadrature-frequency transistor 16 via a terminal 17.

In discussing the operation of the above-described embodiment, it is assumed that resistors 5 and 12 (2.2 kOhm) and resistors 8 and 9 (8.2 kOhm) are of the same value. It is further assumed that the value of resistor 7 with adjustable resistor is equal to the value of resistor 10 (3.9 kOhm).

3a. 1, the current generator consisting of the 4 pnp transistors is closed, and the 3 npn transistor is opened. The capacitor 14, when the source-drain section of the space-controlled transistor 16 is closed, charges the current generator 3 of the 3 npn to the negative voltage until the time t. The voltage of the capacitor 14 decreases linearly with a negative slope (signal b). At time t, the current generator comprising the 3 npn transistor is closed by the rectangular voltage present at terminal I, and the current generator consisting of the transistor 4 is opened. The charge previously stored in the capacitor 14 will then be linearly linearly passed to the t, by the time. In the above-mentioned conditions, a terminal triangle voltage can be obtained at terminal 13, the frequency of which corresponds to the frequency of the quadrilateral voltage present at terminal 1. The switching thus acts as an integrator.

Assuming that the rectangular signal present at terminal I is connected to the lead state of the source drain at each jump, a signal shape is shown at terminal 13. consisting of saw teeth. The polarity of the spindle varies according to the line frequency. If the source-drain section of the spatially controlled transistor 16 is switched to the pulse at terminal 17 ₍ and between the times t ₄ , then the voltage at the signal 1.3 in this range is equal to the ground potential).

According to the valid secam system, the amplitude of the signal thus produced is delimited in the positive and negative directions before the frequency modulation. The pre-demarcation section according to the secam system for the Ü ' _R rows is 15 + 5s and for D rows 18 + 6ps. Accordingly, in the above-described embodiment, the symmetry must be modified. that the output current of the two current generators does not match. In this embodiment, the symmetry can be adjusted by the resistor 7 so that the rise times corresponding to the secam system are created.

The further embodiment shown in FIG. 2 comprises essentially two coupled integrators. The integrator is built with the differential amplifier 18, whose non-inverting input is connected to ground potential, its inverting input 19 is connected via a capacitor 18 to the output of the differential amplifier 18 (terminal 20). The inverting input is 2! a resistor and a quadrant at the terminal 23 having a frequency equal to half the queue frequency through the coupling capacitor 22 and the signal. In this switching variant, the quadrant 23 at the terminal 23 is converted into a triangle b (meander signal). If the signal to the non-inverting input of the differential amplifier 18 is coupled to the ground by the control of the source-drain section of the transistor 24 at the changes in the signal at terminal 23, then the saw-shaped b signal shown in FIG. having a polarity of the saw teeth alternating with the line frequency. The source-drain section of the spatial 24 transistor is controlled by the pulses at terminal 25 and shown in Figure 3. An adjustable voltage divider consisting of resistors 26 and 27 is used to adjust the asymmetry of the saw teeth according to the system of sccam and to set the related rise time. The junction divider is connected to the connection point between the coupling capacitor 22 and the resistor 21. By varying the resistors 26 and 27 of the voltage divider, the desired rise time of the chip signal on the terminal 20, which is dashed in d in Figure 3, can be adjusted.

Claims (10)

Patent claims 1. A method for generating a saw signal for identification pulses introduced into a color video signal of a sec-color television system during a vertical quench, characterized in that a signal of half-frequency (H) meander shape (a) is generated by a function generator of equal frequency, positive and negative generating a signal (b) by means of a controlled switch during the horizontal extinction! to constant potential. A circuit arrangement for carrying out the method of claim 1, characterized in that it comprises a first current generator and a second, complementary current generator connected in parallel. the input of which is connected to a half-frequency (H) meander-shaped signal (a) source and a capacitor (14). one terminal of which is connected to the outputs of the two current generators, the other terminal of which is connected to a constant voltage point, preferably ground potential, and a switching transistor (16). with a controlled switch section on the capacitor! (14) is connected in parallel and a series of frequency pulses (c) are applied to its control electrode (Fig. 1). A circuit arrangement for carrying out the method of claim I, characterized in that it has an integrated circuit built with a differential amplifier (18). the inverting input of which is connected to the output of the differential amplifier (18) via a capacitor (19) and connected to an input terminal (23) via a resistor (21) which has a half-frequency (H) a source of a meander-shaped signal (a) is connected while its non-inverting input is connected to a constant voltage point, and a switch transistor (24) is connected. the controlled switch section of which is coupled between the inverter input of the differential amplifier (18) and the constant voltage point, and a series of pulses (c) are applied to the control electrode (Fig. 2). An embodiment of a circuit arrangement according to claim 2, characterized in that the first current generator comprises an npn transistor (3) having an emitter on a first resistor 10 (3). 5) and its base is connected to a negative voltage via a second resistor (7), and its base is connected to a positive voltage via a series circuit consisting of a third, fourth and fifth resistor (8.9.10). 5. An embodiment of a circuit arrangement according to claim 2, characterized in that the second current generator is a pnp transistor (4) All. having an emitter at a sixth resistor (12). and its base is connected to a positive voltage point through a fifth resistor (10), 20 from the second, third and fourth resistors (7, 8. 9) is connected to a negative voltage point via an appropriate serial connection. 6. An embodiment of a switching arrangement according to any one of claims 2 to 4 or 5, characterized in that At the connection point between the third and fourth resistors (8.9) of a 25-series circuit, the source of the half-frequency (H) meander signal (a) is connected. An embodiment of a circuit arrangement according to any one of claims 2 to 4 or 5, characterized in that The collector of 30 pnp and npn transistors (4.3) is directly connected to one another and is connected to a ground potential point through the capacitor (14). An embodiment of a circuit arrangement according to any one of claims 2 to 4 or 5, characterized in that The switching section of the switching transistors 35 (16 and 24) is a source-drain section of a field-controlled transistor whose gate is a conductor delek wire. 9. An embodiment of a switching arrangement according to any one of claims 1 to 5 or 5, characterized in that the second resistor (7) is adjustable. An embodiment of a circuit switching arrangement according to claim 3, characterized in that the source of the half-frequency meander-shaped signal (a) is applied to the resistor (21) via a coupling capacitor (22) and the coupling capacitor (22). and a junction of an adjustable voltage divider connected to a negative and positive voltage point at the connection point of the resistor (21). 2 pieces of drawing Figure 3 Kt »di« en feid »Public and ioft Publishing * 2 6682 66-42 AJföidt Printing House. Debrecen Feieid * vneiS Benkó download tgazpto