DE1054190B - Process for generating saw tooth tensions with optionally adjustable polarity and / or amplitude - Google Patents

Description

GERMAN

It is already known to have a sawtooth voltage, its polarity and amplitude optionally adjustable is to be generated by means of two sawtooth voltages of opposite polarity. In doing so, these Sawtooth voltages of opposite polarity supplied to each end of a potentiometer; from the tap of the potentiometer - depending on its position - the sawtooth voltage becomes more positive or negative polarity removed. This switching arrangement has the disadvantage that the potentiometer, means whose adjustment is effected, is traversed by sawtooth-shaped currents, so that it is only is remotely controllable with relatively great effort. In addition, there is a switching arrangement for the generation of sawtooth-shaped voltages become known, in which from a DC voltage with adjustable Amplitude and polarity a sawtooth voltage of corresponding amplitude and polarity is generated. The assignment of a capacitor (the other assignment of which is grounded) depends on the The polarity of the direct voltage is periodically charged over one of two oppositely polarized directional conductors and then grounded, so that a sawtooth voltage results. The periodic grounding of the capacitor is carried out with a circuit consisting of four diodes, their cathode-anode routes periodically blocked or conductive by a sequence of square-wave switching pulses will. This known switching arrangement has the disadvantages that a relatively large effort, in particular on diodes, and that also stabilized both a negative and a positive DC voltage is required.

The aim of the invention is to avoid the aforementioned disadvantages of the known switching arrangements.

According to the invention, two control pulse trains of opposite polarity are opposed via one each polarized directional conductor fed to a resistor, the other end of which is via a capacitor is applied to a reference potential (ground). By changing the potential applied to the directional ladders by means of an optionally adjustable or remotely controllable voltage divider, one of the control pulse sequences is generated blocked or let through, and from the respectively let through control pulse sequence the approximate sawtooth voltage is generated by means of a resistor and a capacitor.

The voltage divider used according to the invention is traversed by direct currents, their regulation z. B. also made remotely controllable by means of a variable resistor without any special effort can be.

It is advisable to use two sequences of pulse peaks of opposite polarity as control pulses

for generating sawtooth chipping with optionally adjustable polarity
and / or amplitude

Applicant:

Television GmbH,
Darmstadt, Am Alten Bahnhof 6

Dipl.-Ing. Emil Sennhenn, Darmstadt-Arheilgen, has been named as the inventor

turn, which are derived from a sequence of square-shaped pulses in that the square-shaped Pulses are first differentiated and that then the resulting pulse peaks are more positive and negative polarity are separated by means of a diode each.

Here, the pulse peaks generated are offset from one another in terms of phase, so that the sawtooth voltages derived therefrom have the same phase shift from one another. This This fact is of particular importance with regard to a black control to be carried out.

The invention is explained in more detail below with reference to FIGS. 1 and 2, which illustrate exemplary embodiments. It shows

1 shows a switching arrangement for generating a sawtooth voltage of adjustable polarity, the frequency of which is equal to the television horizontal sync frequency,

2 shows a switching arrangement for generating a sawtooth voltage of adjustable polarity, the frequency of which is equal to the television vertical sync frequency.

The switching arrangement according to Fig. 1 is supplied with a television horizontal pulse 2 (17 V _ss ) at Klemmel and applied to the control grid of the first electrode system of the tube 3 , at whose anode resistor 4 and cathode resistor 5 a negative and positive pulse 6 and 7 respectively is removed. The rectifiers 8 and 9 are used to control the pulses 6 and 7 on their pulse roof. The side of the rectifier facing away from the signal is supplied with a controllable voltage divider - consisting of the resistor 11 and the variable resistor.

809 788/293

Claims (5)

stand 12 - connected. At terminal 13 there is a direct voltage of +150 V. Via the rectifier 14 or 15 - depending on the setting of the voltage divider · - ■ one of the pulses 6 or 7 is fed to the time constant element consisting of the resistor 16 and the capacitor 17 . This time constant element causes a sawtooth-shaped, falling or rising voltage curve, depending on whether the pulses 6 or 7 have been fed to the time constant element. The sawtooth-shaped voltage curve is fed to the control grid of the second electrode system of the tube 3 via the capacitor 18. The amplified sawtooth signal 10 or 10 'is picked up at the resistor 19 and fed via the terminal 20 to an amplifier (not shown) in which it is mixed with an image content signal supplied by a television camera. The purpose of this mixture is to compensate for certain interference voltages inherent in the pickup tubes mentioned. The circuit described has the advantage that it can be operated remotely by changing the DC voltage with little effort. The switching arrangement according to FIG. 2 is supplied with vertical-frequency television synchronization pulses 22 at terminal 21 and the positive and negative pulse peaks 25 are obtained by differentiation by means of the capacitor 23 and the resistor 24. These are separated by the diodes 26 and 27, so that the pulse voltages 28 and 29 result. The diodes 31 and 32 are used to control the peaks of the pulses 28 and 29. In addition, the diodes 33 and 34 are provided, the switching of the diodes 31 and 33 or 32 and 34 being made in such a way that either the diode 33 or the diode 34 is more or less conductive, depending on the potential prevailing in the circuit point 35. This can be set by means of resistors 36, 37 and 38. There is a direct voltage of +150 V at terminal 39 and a direct voltage of -85 V at terminal 41. One of the diodes 33 and 34 is made conductive because the pulse peaks 28 and 29 have different phase positions. The pulse peaks 28 or 29 that are passed through are integrated by means of the resistor 42 and the capacitor 43 and the sawtooth voltages 44 and 45 respectively generated in the process - which have a phase shift t - are amplified by means of the two electron systems of the tube 46. The amplified sawtooth voltage is then fed from the anode of the second electron system in the desired polarity via the capacitor 47 and the resistor 48 to the control grid of the first electrode system of the tube 49. Via terminals 51 and 52, vertical-frequency pulses 22 and 22 'are fed to the differentiating arrangements - consisting of capacitor 53 and resistor 54 or capacitor 55 and resistor 56 - and the resulting pulse voltage 57 and 58 are separated by means of diodes 59 and 61, see above that the pulse voltages 62 and 63 arise. Clamping pulses - for clamping the sawtooth miniature pulses 44 and 45 during t - are derived therefrom. The clamping takes place by means of the clamping stage 64 in the circuit point 65 to black potential. The blanking signal supplied at terminal 65 is added at the anode of the first electrode system of the tube 49. Since no black control is possible on the grid of the second electrode system of the tube 49 due to the added blanking signal, the sawtooth provided with blanking is placed on the control grid of the second electrode system of the tube 49 via a glow lamp and a DC voltage coupling is achieved in this way. The sawtooth voltage is conducted from the anoid of the second electrode system of the tube 49 via the diode 66 for the purpose of cutting off the signal to the output terminal 67. The sawtooth signal is fed via this output terminal 67 to an amplifier (not shown) in which it is mixed with the picture content signal coming from a television pick-up tube for the purpose of compensating for interference signals. These interfering signals arise, among other things, from uneven scene lighting. If necessary, the sawtooth voltage with positive or negative polarity is mixed in, depending on which of the two sawtooth voltages best compensates for the interference signal present in each case. It is of great advantage that the sawtooth signals generated can be adjusted remotely. Patent claims: 1. A method for generating a sawtooth voltage with optionally adjustable polarity and / or amplitude, characterized in that two control pulse trains (6, 7 or 28, 29) of opposite polarity each via an oppositely polarized directional conductor (14, 15 or 33, 34) a resistor (16 or 42) are fed, the other Emde via a capacitor (17 or 43) to a reference potential (ground) that by changing the potential applied to the directional conductors (14, 15 or 33, 34) by means of an optionally adjustable or remotely controllable voltage divider (11, 12 or 36, 37, 38) one of the control impulses (6, 7 or 28, 29) is blocked or allowed through and that from the respectively passed control pulse sequence (6, 7 or 28, 29) by means of a resistor (16 or 42) and a capacitor (17 or 43) the sawtooth voltage (10 or 10 'or 44 or 45) is generated. 2. The method according to claim 1, characterized in that two sequences of pulse peaks (28, 29) of opposite polarity are used as control pulses. 3. The method according to claim 2, characterized in that the two sequences of pulse peaks (28, 29) are derived from bucket sequence of rectangular pulses (22) in that the rectangular pulses (22) are first differentiated, and that the resulting pulse peaks (25) positive and negative polarity are separated by means of a diode (26, 27) each. 4. The method according to claim 1, characterized in that the two control pulse trains (28, 29) are offset from one another in terms of phase. 5. The method according to claim 1 and 4, characterized in that by means of two oppositely polarized further diodes (31, 32) which are connected with one pole each to ground and with their other poles to each end of the directional conductor (33, 34), a control on the peaks of the control pulses (28, 29) is carried out in such a way that only one of the directional conductors (33, 34) is open, depending on the potential which is at