DE1084305B - Circuit arrangement for pulse deformation - Google Patents

Description

GERMAN

The invention relates to a transistor circuit arrangement for shortening, lengthening and shifting pulses using a Oscillating circuit.

According to the invention, the emitter of the transistor is influenced by the pulses to be reshaped negative pulses applied to block the normally conductive base-emitter path, and Furthermore, the resonant circuit is conductively connected to the collector of the transistor and is through the Blocking of the base-emitter path triggered to a negative half-wave. The following opens positive half-wave of the oscillation the collector base section via a preferably controllable Resistance from the resonant circuit to the base of the transistor, and the positive half-wave is strongly attenuated. The invention has the advantage that the pulse widths of the derived pulses only from the Resonant circuit data depend, however, on the transistor properties and in particular on temperature changes are independent. The circuit arrangement according to the invention is also particularly distinguished by simple structure and is very reliable.

It is advisable to connect the base of the transistor to ground with low resistance in terms of alternating current. The base of the transistor should be conductively connected to the resonant circuit via a resistor be. In a preferred embodiment, square-wave pulses of negative polarity are generated via time constant elements with a relatively large time constant fed to the emitter of the transistor, so that at the collector Pulses can be removed, the duration of which is less than that of the square-wave pulses.

In the following the subject matter of the invention and embodiments thereof with reference to the 1 to 4 described in more detail, the same circuit elements or pulse trains having the same numerals or letters. Show it

Fig. 1 and 2 transistor circuit arrangements for generating pulses, the width of which is predetermined compared to Impulses is increased or decreased,

Fig. 3 pulse trains as they occur in circuit arrangements according to Figs. 1 and 2,

4 shows a circuit arrangement for blanking television camera signals in a schematic representation.

The circuit arrangement according to FIG. 1 is supplied via terminal 1 and the capacitor 2 (1 μ ¥) square-wave pulses A (FIG. 3). The input time constant given by the capacitor 2 and the resistor 3 is relatively large, so that the pulse A is insignificantly deformed and the pulse B is fed to the emitter of the transistor 4 (pnp transistor of the OC 410 type). Through the leading edge of the circuit arrangement
for pulse deformation

Applicant:

Television. GmbH,
Darmstadt, Am Alten Bahnhof 6

Dipl.-Ing. Hans-Robert Groll, Darmstadt,
and Dipl.-Ing. Burkart Brembach.,

Darmstadt-Eberstadt,
have been named as inventors

Pulse B , the normally open base-emitter path of the transistor 4 is blocked. As a result, the voltage at the collector approaches the value of the applied operating voltage. The oscillating circuit in the collector circuit, consisting of inductance 6 (type 1100N22 56T6, 60 turns 0.25) and capacitance 7 (200 pF), swings negatively, so that a negative half-wave from the collector of transistor 4 via terminal 8 is removable. As the collector becomes weakly positive during the positive half-wave of the oscillation, the pn layer between the base and the collector, which is normally biased in the reverse direction, is opened and the resonant circuit is opened on the one hand via this separating layer and on the other hand via the low-resistance circuit of the base through the capacitor 9 ( 2 μΡ) attenuated. As a result, the positive half-wave of the oscillation does not have any effect, so that pulse C can be removed via terminal 8. Pulses C, which are wider than the input pulses B, are not generated because at the end of the pulse B the transistor 4 opens and the resonant circuit is damped. So that the amplitudes of the oscillation cannot become too large, which could damage the transistor 4, the resistor 11 (5 kfi) and the capacitor 5 (1 μΡ) were provided and the collector voltage was measured accordingly. The operating voltage applied to terminal 12 is - 9VoIt. The basic bias voltage can be set by means of the potentiometer 13.

If the capacitor 2 of the circuit arrangement shown in FIG. 1 is replaced by the capacitor. 2 '(10 nF), pulses can also be generated

009 548/286

which are wider than the input pulses. For this purpose, pulses D of positive polarity are supplied via terminal 1. The input time constant given by the capacitor 2 'and the resistor 3 - is now selected in such a way that the pulse sequence E results at the emitter of the transistor 4. The positive "peak of this" pulse sequence, which originates from the leading edge of the pulse D , causes the further opening of the ^; "Base-emitter path of the transistor. Since this works in the normal working range, this peak is only amplified, but no oscillation will develop, since the oscillating circuit is dampened by the conducting transistor. The negative trailing edge of the pulse £ causes the transistor to block, however, so that the resonant circuit formed by the inductance 6 and the capacitor 7, as already described, starts to oscillate to the negative half-wave. The positive half-wave is suppressed again, so that the pulse sequence F can now be removed via terminal 8, the leading edge of which coincides with the trailing edge of the Pulse D coincides.

In some cases it is desirable to generate broadened pulses from given pulses, the leading edges of which coincide in time with the leading edges of the given pulses. With the circuit arrangement according to FIG. 2, such a widened pulse can be generated. Pulses D are supplied via terminal 1 and pulses F are taken from the Kellektor of the transistor 4 and supplied to the base of a further transistor 15 via the resistor 14 (10 kΩ). The pulses D are also fed to the emitter of the transistor 15 via the resistor 16 (2 kΩ) and the capacitor 17 (50OnF), a pulse train G being produced . A mixture of the pulses G and the pulses supplied via the resistor 14 takes place in the transistor 15 , so that an output signal H can be tapped at the collector of this transistor. The resistor 18 (2 kΩ) was provided as the emitter resistor and the resistor 19 (5 kΩ) as the collector resistor.

In television technology, circuits according to FIGS. 1 and 2 can be used in many ways for pulse shaping be used. For example, blanking pulses are used to blank the image signals supplied by television cameras required, which are narrower than the main blanking pulses. This fact is now described in more detail with reference to FIG. In the pulse center 21, among other things, television horizontal synchronization pulses generated, the duration of which corresponds to 11% of the duration of a row, and the transistor circuit arrangement 22 supplied, in which (similar to the circuit arrangement according to FIG. 2) pulses are generated whose duration 14Vo corresponds to the line duration. From the television horizontal sync pulses the pulse center 21 so broader pulses are derived and as camera horizontal blanking signals the television camera 23 for the purpose of blanking the image content signal. The blanked image content signal is then fed via the line 24 to the main amplifier 25, in which the main blanking of the image content signals using 18% wide horizontal blanking pulses (supplied is made by the pulse center 21).

Instead of the transistor circuit arrangement 22, the transistor circuit arrangement 22 'can also be used. Use (similar to the circuit arrangement according to FIG. 1) and thus from the horizontal blanking pulses (Width 18%) generate narrower pulses (width 14%) and use them as camera horizontal blanking pulses. Similar uses exist in television picture and animation mixers. In the latter, a method according to Fig. 1 can be used to generate pulses in the center the horizontal blanking interval begin.

Television horizontal sync pulses can be used to generate clamping pulses negative polarity, the duration of which is preferably 11% of the line duration, are fed to the emitter of transistor 4,

ίο so that 4 pulses can be removed from the collector of this transistor are. These are possibly after further reshaping, for example limitation, as clamping pulses with a duration of preferably 7% of the line duration televisions for the purpose of reintroduction supplied to the direct current component.

Claims (7)

Patent claims: 1. Transistor circuitry for shortening, lengthening and shifting pulses using an oscillating circuit, characterized in that the emitter of the transistor (4) negative pulses are supplied under the influence of the pulses to be transformed for the purpose Blocking of the normally conductive base-emitter path and that the resonant circuit (6,7) is conductively connected to the collector of the transistor and by blocking the base-emitter path is triggered to a negative half-wave, the subsequent positive half-wave of the oscillation, the collector base section Via a preferably controllable resistor (13) from the resonant circuit to the base of the transistor opens and the positive half-wave is strongly attenuated. 2. Circuit arrangement according to claim 1, characterized in that the base of the transistor (4) is connected to ground with low resistance in terms of alternating current. 3. A circuit arrangement according to claim 1, characterized in that square pulses (A) of negative polarity via time constant elements (2, 3) with a relatively large time constant are fed to the emitter of the transistor (4) so that pulses (B) can be removed from the collector Duration is less than that of the square-wave pulses (A). 4. A circuit arrangement according to claim 1, characterized in that square pulses (D) of positive polarity are fed to the emitter of the transistor (4) via time constant elements (2 ', 3) with a relatively small time constant, so that pulses at the collector of this transistor (4) (F) longer duration can be removed, the leading edges of which coincide in time with the trailing edges of the rectangular pulses (D) of positive polarity. 5. Circuit arrangement according to claim 4, characterized in that the pulses (F) of longer duration are fed to the base of a further transistor (15) that the emitter of this further transistor (15) square pulses (D) of positive polarity via an i? C- Member (17,16) are supplied so that pulses (H) can be removed from the collector of this further transistor (15), the leading edges of which coincide in time with the leading edges of the rectangular pulses of positive polarity (D) and whose duration is greater than that of the rectangular pulses of positive polarity (D) is. 6. Circuit arrangement according to claim 1 and 3, characterized in that television horizontal synchronous pulses of negative polarity, the duration of which is preferably 11% of the line duration, the Emitter of the transistor (4) are fed, so that at the collector of this transistor (4) pulses are removable, possibly after further reshaping, for example limitation, as clamping pulses with a duration of preferably 7% of the line duration televisions for the purpose of reintroduction are supplied to the direct current component. 7. Circuit arrangement according to claim 1, 4 and 5, characterized in that television horizontal sync pulses, whose duration is preferably 11% of the line duration, the emitter of the Transistor (4) are fed, so that at the collector of the further transistor (15) pulses are removable, which - possibly after further reshaping - as a camera horizontal blanking signal are fed to a television camera (23) with a duration of preferably 14% of the line duration. 1 sheet of drawings