DE1182289B - Circuit arrangement for generating pulses - Google Patents

Description

Circuit arrangement for generating pulses The invention relates based on a circuit arrangement for generating square-wave pulses with a predetermined sequence of sync pulses is synchronized. The duty cycle should be these square-wave pulses in particular remain constant when the repetition frequency the sync pulse changes.

In a known multivibrator circuit with two tubes, the Circuits the output electrodes of each tube through a capacitor to the control grid circuit the other tube, and is between the control grids of the two tubes a resistor switched on. An adjustable tap point for this resistor is connected to the circuit point to which the cathode lines of the two Tubes are connected. By setting this between the control grids of the the two tubes connected resistance is the pulse repetition frequency of the generated Square-wave pulses can be set manually, whereby their duty cycle remains constant. This known multivibrator circuit is therefore not suitable for that of the invention to solve the underlying task. Because this multivibrator circuit is not with a predetermined sequence of sync pulses so synchronized that the Duty cycle of the generated square-wave pulses remains constant even if the repetition frequency of the sync pulses changes.

According to a known method for regulating the width ratio of the two curve sections of a meandering voltage become the positive ones and negative amplitudes of the DC-free meander voltage after rectification Connected to each other via a peak rectifier, and this becomes a control voltage gained, either directly or via a control tube, the width ratio of the two Curve sections of the meander voltage influenced in such a way that with a different duty cycle a control process is triggered which determines the deviation in the pulse duty factor that has occurred undo. The circuit arrangement according to the invention also causes one, keeping the duty cycle constant, but goes a different way.

According to the invention, a coupling capacitor is known per se connected to the control electrode of an amplifier stage, which is in switching mode works, and via this coupling capacitor are also known per se Way input pulses are supplied, the sawtooth-like pulses at the control electrode and the square-wave pulses to be generated at an output electrode of the amplifier stage cause. If the input pulses supplied do not have a sawtooth shape, must they are reshaped accordingly. Depending on the mean value of these square-wave pulses becomes - preferably using a charging capacitor - a control voltage derived and thus such a change in the direct current component of the sawtooth-shaped Impulse causes the duty cycle of the sequence of square-wave impulses (also with changing repetition frequency of the input pulses) remains largely constant.

The invention has proven itself particularly in the field of television technology and can be used, for example, to generate vertical frequency blanking pulses will; their pulse duration compared to a given sequence of blanking pulses is enlarged. This can be done by offsetting the trailing edge of the given blanking pulses and / or caused by offsetting the leading edge of the predetermined blanking pulse will.

For example, if a television recording device consisting of a television camera and an operating device, optionally according to one of several different television standards are to be operated, then blanking pulses are required, their pulse duration varies depending on the television standard in question should be, whereas the duty cycle of such blanking pulses in all standards is approximately the same. The subject of the invention can thus be used for automatic Regulation of the pulse duration of the blanking pulses can be used. When switching the mode of operation of such a television set of, for example, 625 lines A special setting for the duration of the blanking pulses is not necessary on 405 lines. in the The following is an embodiment of the invention with reference to the F i g. 1 and 2 described. It shows F i g. 1 shows a basic illustration of a circuit arrangement for generating square-wave pulses with a constant duty cycle using a single transistor stage, F i g. 2 pulse trains as they are in the circuit arrangement according to FIG. 1 occur.

The circuit arrangement according to FIG. 1 consists of transistors 31, 32 (types 0C 77), resistors 33 (500 ohms), 34 (22 kOhm, 35 (15 kOhm), 36 (4.7 kOhm), 37 (2.2 kOhm) , 38 (1 kOhm), further from the capacitors 39 (100J), 41, 42, 43 (all 50 J each) and from the diode 44. The circuit arrangement is via terminal 45 with the negative pole (-60 volts) of an operating voltage source whose other pole is connected to ground, and terminal 46 is connected to a fixed potential source.

The circuit arrangement according to FIG. 1, input pulses H are supplied via terminal 47 and the square-wave pulses B to be generated are emitted via terminal 48 , the pulse duty factor T / t of which should remain constant even if the pulse repetition frequency of the specified input pulses H changes. The input pulses are thus fed to the base of the transistor 31 via the capacitor 39. Since this transistor 31 works in switching mode, the sawtooth-shaped course of the input pulses H is interrupted when the opening potential is reached, and in this way the pulses 1 arise at the base of the transistor 31 Base-emitter path of transistor 31 short-circuited to ground. Subsequently, the square-wave pulses B arise at the collector of this transistor 31 , which are thus fed to the terminal 48 on the one hand and to the charging capacitor 43 via the capacitor 41 and the resistor 37 on the other hand. In this way, a control voltage is produced in the circuit point 21, which control voltage is fed to the base of the transistor 31 via the impedance converter 42 - consisting of the transistor 32 and the resistor 38. This control voltage arising in the circuit point 21 is dependent on the mean value of the square-wave pulses B and thus on their pulse duty factor. If the pulse repetition frequency of the given input pulses changes, then the mean value of the square-wave pulses B also changes. Depending on this mean value, the direct current component of the pulses 1 is changed in such a way that the duty cycle of the square-wave pulses generated remains constant. If, in particular, instead of the input pulses H, the input pulses H 'are fed via terminal 47 , then, as a result of this regulation, the pulses I' are generated at the base of the transistor 31 and, subsequently, the square-wave pulses B ', the duty cycle of which is T', at the collector of the transistor 31. lt ' = Tlt is.

The resistors 35 and 36, the capacitor 42 and the diodes 44 serve only to adapt the transistor 32 in terms of DC voltage to the amplifier stage with the transistor 31 and the working resistor 34.

Claims (3)

Claims: 1. Circuit arrangement for generating a sequence of square-wave pulses, the duty cycle of which remains largely constant even when the repetition frequency of predetermined sync pulses changes, characterized in that a coupling capacitor (39) is connected in a manner known per se to the control electrode of an amplifier stage (31) , which works in switching mode that via this coupling capacitor (39) input pulses (H) are supplied in a manner also known per se, which cause sawtooth-like pulses (I) on the control electrode and square-wave pulses (B) on an output electrode of the amplifier stage (31) Depending on the mean value of these square-wave pulses (B) - preferably using a charging capacitor (43) - a control voltage is derived and that this control voltage causes such a change in the direct current component of the sawtooth-like pulses (I) that the duty cycle of the sequence of square-wave pulses ( B) largely ko remains constant. 2. Circuit arrangement according to claim 1, characterized in that the coupling capacitor (39) is connected to the base of a transistor (31) , the emitter of which is grounded to one pole of an operating voltage source and the collector of which is connected to the second pole of a working resistor (34) Operating voltage source is conductively connected, that the collector of this transistor (31) is connected to a fixed potential via a further resistor (37) and via the charging capacitor (43) and that the transistor-side assignment of this charging capacitor (43) to the base of the transistor (31) is conductive connected is. 3. Circuit arrangement according to claim 2, characterized in that the transistor-side end of the charging capacitor (43) is connected to the input of an impedance converter (42) , the output of which is connected to the base of the transistor (31) .