DE925832C - Rectifier circuit with anode rectification for negative modulation in television sets - Google Patents

Description

Rectifier circuit with anode rectification for negative modulation for televisions It is common practice for televisions to reproduce the image signals after rectification, which is coupled with a so-called black control, while maintaining the DC component to amplify and then galvanically to the electrode to be controlled of the Braunschen To give tube. The circuit must be designed in such a way that, if there is no transmitter is received, the Braun tube is dark or not so bright that the Braun tube Tube can be destroyed ..

Because of this condition, television sets use negative modulation Anode rectification not used, which although it has the advantage of great simplicity, but with negative modulation without a signal the same voltage as with the signal>,> know < gives away. The invention adapts the anode rectification to the above condition at. It consists in that the negative grid bias necessary for the anode alignment from the peak voltage of the, high or intermediate frequency voltage (referred to as HF for short) is generated by grid rectification.

Fig. I shows an example of a circuit: Tube Tube i is the last HF tube. The HF is applied to the grid of tube Rö 2 via C2. The tube Rö z is the image signal amplifier tube, which also takes over the anode rectification. R2 is the anode resistance., Fig. 6 shows the function of the circuit with the IjU, - characteristic curve K of the tube Rö 2 and the high frequency and the image signals B. The peak voltages Sp of the HF, shown in Fig. 6 as the synchronization signal, generate a Grid current that charges the capacitor C1 via the coil L1, which can be a choke or as an inductance to the last HF circuit. The time constant of C1 with the discharge resistance R1 must be greater than the time interval between the peak voltages. The voltage across C1 acts as a grid bias (A in Figure 6) and can be adjusted with the RF gain. This simultaneously changes the size of the image signals rectified via the anode current characteristic. With negative modulation, the synchronization signals are always controlled down to grid voltage zero regardless of their size and independent of the remaining signal content. The circuit also serves to keep the synchronization signal constant, similar to low-frequency circuits who use the grid current during the pulses to reintroduce the DC value. If there is no high frequency, since there is no voltage drop across the cathode resistor, the grid bias is O, and the anode current maintains the value BO in Fig. 6, i.e. the tube is dark. One can: also introduce a low grid voltage at the base point of R1 (see A1 in Fig. 6) without endangering the function of the circuit. Al can be selected so that the anode current of the tube: 2 equals the value Bi has. Experiments have shown that the circuit according to Fig device according to Fig. 3 and 7 - is by and large electrically identical, is extraordinarily powerful despite its astonishing simplicity. All that can be said about Fig. 3 is that C2 R5 must be greater than the period of the high frequency. In Fig. 7, C2 R6 must be greater than the time interval between the HF peak voltage. In addition to the low cost and the already mentioned advantages, the following should be particularly emphasized: The low-frequency bandwidth is very favorable, since chokes only have to be used at one point. The characteristic curve is very steep in the vicinity of the -zero level, and the white values can be set in such a way that they lie in the flat part of the characteristic with appropriate control. The characteristic curve of the Braun tube, on the other hand, is flat with a low control voltage and very steep with a large one. The circuit according to the invention can therefore compensate for the characteristic of the Braun tube, which means that the gradation of the dark areas of the image is more favorable. The characteristic is fully controlled, which ensures a high output voltage.

The circuit according to Fig. I is also significantly less hum-free than one normal rectifier and image signal amplifier circuit, since the grid is over the very small L1 and the capacitor Ci is practically grounded. As a result of the low DC resistance of L1, the synchronization signals are severely cut, d. H. Interferences that are on the synchronization signals are suppressed. Nevertheless the synchronizing signals come through powerfully because their amplification is steepest Part of the characteristic takes place. A further advantage can be mentioned that A DC voltage is available across C1, which is easily used for automatic control the high-frequency stages can be used (see U in Fig. i).

An advantageous further embodiment of the invention is also shown in the circuits according to Fig. 2, q. and 5 shown.

In Fig. 2, resistor R3 is connected upstream of C1, which can optionally be bridged by a small capacitor C5. A voltage is applied to R3 as a result of the charging surges during: the impulses, while R3 is de-energized for the rest of the time. The possibly overlying low HF can, however, be derived from C5. The impulses are above R3, ie in this case the separation of image content and impulses is also taken over by the circuit.

In Fig.q. and 5 the cathode resistor R4 has been added, at which the image signals Uk can also be picked up in the opposite polarity as at the anode resistor R2. C1 ends at the cathode instead of at ground, so that no negative feedback from R4 occurs. The resistors R1 can also optionally end at the cathode here. In Fig. 5 the base point L1 is connected to C, to earth, in order to give the HF, which is located from the tube i via C2 and L1, a discharge . In this case the bandwidth of the voltage Uk is lower.

Claims (13)

PATENT CLAIMS: i. Rectifier circuit with anode rectification for negative modulation in television sets, characterized in that the negative Grid prestress for shifting the operating point into the kink of the characteristic curve through grid rectification of the peak voltages of the high or intermediate frequency is won. 2. Rectifier circuit with anode rectification according to claim i, characterized in that the via a capacitor (C2) from the last high-frequency tube fed to the grid of the image signal amplifier and anode rectifier tube High frequency or intermediate frequency peak voltages generate a grid current, which charges a capacitor (C1) via a coil {L1), the voltage of which is negative Grid prestress is the shift of the operating point in the curve of the curve causes. 3 ,. Rectifier cladding with anode rectification tightly according to the claims i and 2 ,, characterized in that the time constant of the charging capacitor C1 with its discharge resistance R1 is greater than the time interval between the peak voltage. q .. Rectifier circuit with anode rectification according to claims i to 3, characterized in that the grid at the base of the leakage resistance of the capacitor one small additional bias is supplied, which is appropriate is chosen so that the anode quiescent current is at the level of the image signal zero. Rectifier circuit with anode rectification according to claims i to q., Thereby characterized in that the synchronizing signals are clipped by the grid current and be equalized. &. Rectifier circuit with anode rectification according to the Claims i and 2, characterized in that for .simultaneous separation of the A resistor (R3, Fig. 2) is connected upstream of the charging capacitor for impulses from the image content which is bridged by a small capacitor (C5) if necessary. 7. Rectifier circuit with anode rectification according to claims i and 2, characterized in that the charging capacitor is preceded by a resistor (R5, Fig. 3 ) instead of the coil and that the coupling capacitor (C2) between the last high-frequency tube and the image signal amplifier tube and the period determined by the upstream resistor (R5) is greater than the period of the high frequency. B. Rectifier circuit with Ahoden rectification according to claim i, characterized by the fact that the last High-frequency tube to the grid of the signal amplifier and anode rectifier tube supplied peak voltage of the high or intermediate frequency generates a grid current, which create the desired grid prestress at a discharge resistor (R6, Fig. 7) leaves, and that by the coupling capacitor (C2) and the bleeder resistor RE certain time constant is greater than the time interval between the high-frequency peak voltages. 9. Rectifier circuit with anode rectification according to claims i to 8, characterized in that the DC voltage produced on the charging capacitor is used for the automatic regulation of the high frequency stages. ok Rectifier circuit with anode rectification according to claims i to 9 @, characterized in that an additional resistor (R4, Fig. q. and 5) is switched on in the cathode line and the charging capacitor is connected to the cathode instead of earth. i i. Rectifier circuit with anode rectification according to Claim io, characterized in that that the discharge resistor (R1) belonging to the charging capacitor (C1) is also connected to the cathode is switched. 12. Rectifier circuit with anode rectification according to the claims io and ii, characterized in that the image signals (Uk) are also applied to the cathode resistor (R4) can be removed with the opposite polarity than at the anode resistor (R2). 13th Rectifier circuit with anode rectification according to claims io to i2, thereby characterized in that the base of the with the grating of the image signal intensifier tube connected coil (L1, Fig. 5) is connected to earth via a capacitor (C3). Dressed Dirty writings: "Use of the electron tube in radio receivers and amplifiers" (N.V. Philips, Eindhoven), Book 1, 1949, pp. 3773'78; Kammerloher: »High frequency technology, Part III: rectifier ", p. 331 ff.