DE1170995B - Method and circuit arrangement for the operation of image recording tubes of the superorthicon type - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Boarding school KL: H 04 n;

HOIj
German KL: 21 al -32/35

Number: 1170 995

File number: F 36314 VIII a / 21 al

Filing date: March 7, 1962

Opening day: May 27, 1964

The invention relates to a method for operating image pickup tubes of the superorthicon type, in which the scanning is blocked during the deceleration time of the deflection devices.

In the operation of superorthicon cameras, it has previously been customary to use the beam current of the superorthicon tube not to block during the return times of the scanning beam, but to block the storage electrode during negative bias of the blanking interval of the amplifier. Since then the scanning beam on the storage electrode cannot land, it is not modulated during the blanking times. There is a certain flowing The beam current corresponding to the blanking value of the image signal, which is fed in full strength into the secondary electron multiplier got. Since the blanking value usually serves as a reference value for clamping the amplifier, one needs a constant value that is as constant as possible Signal value. In the operating mode described above, however, the signal value is during the Blanking interval superimposed a noise signal, which means that reference values differ from line to line generated for the clamping, which causes line noise.

In order to overcome this disadvantage, it is known to reduce the beam current of the superorthicon tube during the To block the blanking interval in order to obtain a constant reference value for the clamping of the amplifier. This requires automatic beam current regulation to a very constant one for the following reason Value.

When the superorthicon tube is fully modulated by the light falling on the photocathode, the scanning beam is usually 50 ¹ Vo modulated. Only half of the electrons of the beam current offered to the storage electrode for scanning or erasing the charge image can land on the storage electrode. The maximum beam current value results during the negative scanning of the storage electrode. During the scanning of white image areas, this decreases to half the value. When the beam current is suppressed, the total signal amplitude is about twice as large as with the so-called black-and-white jump. The clamping circuits of the amplifier work on this potential value, the so-called blanking value, which occurs when the beam current is suppressed. When the beam current changes, both the black level and the white level potential are changed in the image signal; because the potential reached in the amplifier when the beam current is suppressed is retained by the clamping circuits. It should therefore, in order to define potential values for black and white and also method and circuit arrangement for
Operation of image pickup tubes of the
Super orthicons

Applicant:
TV G. mb H.,

Darmstadt, Am Alten Bahnhof 6

Named as inventor:
Dr.-Ing. Wolfgang Dillenburger,
Nieder Ramstadt via Darmstadt

To obtain all intermediate gray values, the beam current must be kept at a very constant value.
In known circuits for automatic beam current stabilization, attempts have been made to derive a control voltage for regulating the Wehnelt bias voltage from the current flowing to the anode of the beam system or from the cathode current of the superorthicon tube. However, the very different, sometimes relatively low insulation resistance between the different electrodes of the beam generating system between the individual tube specimens causes great difficulties in the implementation of such circuits, so that the insulation current that occurs can be of the same order of magnitude as the beam current. The two currents add up and cannot be separated from one another by any means, so that at best the value of the total current and not the beam current alone is stabilized. In order to circumvent this disadvantage, one could select suitable superorthicon tubes according to their insulation resistance, but this would increase the reject rate considerably.

The method according to the invention avoids the disadvantages listed above and is characterized in that the beam current is blocked only during part of the blanking time and at least during another part of the blanking time, the storage electrode is switched on in a manner known per se negative potential is applied to the beam cathode and that the output from the amplified

409 597/167

The DC voltage derived from the image pickup tube determines the strength of the beam current influencing electrode, preferably the Wehnelt electrode of the beam system, in the sense of a automatic stabilization is applied.

The output current of the secondary electron multiplier is accurate to the beam current in a vacuum proportional, so that its size during the negative scanning of the storage electrode

F i g. 1 shows part of the circuit of a television camera. Here is a superorthicon tube 1 with the storage electrode 2, the cathode 3, the Wehnelt electrode 4 and the beam anode 5 shown, wherein 5 the beam anode at the same time the impact electrode of the secondary electron multiplier 6, which also comprises the electrodes 7 and the anode 8.

The storage electrode 2 is supplied with a pulse C, which the storage electrode during the entire

tion resistance between the electrodes of the beam io th return time of the scanning beam against the beam system is independent measured variable, which biases negative to the cathode 3. The Wehnelt electrode 4 automatically keeps the beam current constant during part of the return time which can be worn out. The prerequisite for the scanning beam by a pulse B so far negative demonstration of the method is that the amplification of the tensioned that the beam current is blocked. While the multiplier is constant, what becomes in practice 15 the blocking of the beam current is e.g. B. in the Ausais has proven to be fulfilled. A feed line of the secondary electron multiplier 6 control voltage derived from it is then keyed in by a counter pulse D from insulation faults. During this time going independently. It can now also be used to keep the beam current constant by influencing the bias voltage of the amplifier 12 and the measuring amplifier stage 13, ao pulses E , to the preamplifier 11, the main power.

By appropriate biasing of a secondary To further explain the invention

emitting electrode, the multiplier can now use the pulse shapes of the F i g. 3 discussed which a predetermined gain factor in such a way the course of the various expedient in the be made that the automatic control of tube camera represent the pulses used for to tube works optimally, so that the maximum beam current stabilization is always used. It is made out of it possible control steepness of the arrangement achieved that it is necessary that the image is on. acquisition tube (superorthicon tube) downstream

The clamping pulses should lie within the blanking amplifier at a certain signal value at the clamping time of the beam current. At other times within, so that a fixed half of the blanking time is independent of the image content, the storage electrode should be biased to a negative ₃₀ reference value (eg white or black value) despite the tive. During this time, using AC amplifier stages, the beam current also reaches its maximum value. Im assures it is. The purpose of maintaining this reference image signal is therefore a pulse, the height of which is used as the clamping pulse E , which is approximately equal to the double black-and-white jump. Ramp-down time at the point in time to the amplifier - According to a further feature of the invention, ₃₅ stages are set at which a defined signal level is present for the duration of the amplifier (e.g. white or black level). Clamping pulses a black pulse to the image signal at I _n in FIG. 3 is A

appropriate place added. The amplitude of this Im- a reference pulse, of whose flanks the shift pulse is as large as the signal jump between those control and tactile pulses of a television camera blocked and unmodulated beam current, so that _{40 are} diverted. In the present case, the pulse creates a constant black level that is generated during the line retrace time, which is used as a reference value for clamping the pulse. Video amplifier stages can now serve as a reference value prescribed. In a Vari Bener image amplitude during the time the clamping Ante the invention, the amplitude of the black can pulses to have available is the Wehimpulses also the signal change between blanking ₄₅ neltelektrode optionally a blocking pulse B 4, which value corresponding to the beam current and white level , so by blanking the beam, an image signal at the outlet through the pulse makes a constant white level appear as the output of the tube, which is obtained about the ampli reference value for the clamping. tude corresponds to a white value of 200 ° / o. This

It is a particular advantage of the invention that the image signal between t _t and t ₂ appears by rectifying a ₅₀ in turn in which the signal voltage at the output is AC voltage, the curve F representing a periodically recurring tube. Basically the minimum and maximum value this pulse value can also be obtained as a reference value for the. This can be used by peak level black level maintenance in the amplifier for the rectifier immediately after the preamplifier. However, it is suitably a counter pulse image signal whose gain is also constant, ₅₅ of the waveform D at the output of the secondary event, the electron multiplier 6 in the image signal taken-In the following samples the invention and a training which the amplitude of between t (and t ₂ 'guide for the same g with reference to F i 1 to 3 prevailing image signal to a desired value described in more detail, corresponding to each other, for example, white or -.. as shown in the broken parts or curves in all figures with the same reference 60 Curve - brings it to the reference value black, are marked with reference numbers for the sake of simplicity

TV cameras known per se. The invention works
but from the realization that there is little point
to clamp the image signal to a fixed predetermined reference value as long as the beam current cannot be reliably kept constant. Therefore, now is the stabilization according to the invention
of the beam current a blanking of the storage elec-

Only the parts required for understanding the invention are shown in the illustration. It shows

Fig. 1 is a block diagram of an embodiment of the invention,

2 shows a circuit arrangement for extraction
the control voltage according to Fig. 1,

Fig. 3 Diagrams of the pulses occurring.

trode 2 made with a pulse of the form C, the duration of which goes beyond _{the duration ί 1} -ί _{2 of} the Wehneltaustastung up to t _3. This results in a signal curve as shown in curve F between I ₁ and t _s . At the same time, the beam current receives a modulation according to the curve G, ie it is blocked between I ₁ and t ₂ and at its maximum value between t ₂ and t _s. This is obtained because if the storage electrode 2 is negatively touched but the Wehnelt electrode 4 is opened, the full beam current can reach the secondary electron multiplier 6. This curve G with a beam current fluctuation between ζ = 0 and i = I _max enables the use of peak rectification to obtain a control voltage with the aid of which the beam current can be kept constant despite possible fluctuations in the cathode emission.

The implementation of the switching functions described above will now be explained in more detail with reference to FIGS. The charge image arising on the storage electrode 2 is scanned by means of the electron beam which goes back to the first impact electrode of the secondary electron multiplier 6 and is amplified there. The amplified signal is taken from the anode 8 of the secondary electron multiplier and fed in a known manner via the preamplifier 11 to the main amplifier 12, to which two clamping pulses E are fed. To carry out the method according to the invention, the output of the preamplifier 11 is connected to a circuit arrangement for obtaining the control voltage. This consists of the measuring amplifier stage 13, which is also supplied with clamping pulses E , the peak rectifier stage 14, in which the beam current intensity is determined, and the control voltage amplifier stage 15, which amplifies the direct voltage derived from the pulse signal. The output of stage 15 is connected to the Wehnelt electrode 4 for regulating the Wehnelt bias voltage.

In Fig. 2 shows the circuit arrangements 13, 14, 15 for obtaining the control voltage. The signal coming from the preamplifier 11 is fed at point 16 to the measuring amplifier stage 13, which is provided with clamping pulses E at point 17. After the signal has been amplified in the measuring amplifier stage 13, it reaches the peak rectifier stage 14. The rectified signal is applied to the base of the transistor 18 (OC 450) of the control voltage amplifier stage 15 after direct current amplification. The emitter of transistor 18 is connected to a direct voltage of -55 V, the collector via a resistor ^ (18 kΩ) to a voltage of −125 V. In addition, the collector of transistor 18 is connected to the Wehnelt electrode 4 connected. Depending on the size of the control voltage prevailing at the base of the transistor 18, the transistor is controlled from the conductive (at a control voltage of 0V) to the blocked state (at a control voltage of 5V), so that the voltage prevailing at the point 22 from -55 V to can be about -125 V, whereby the Wehnelt bias voltage is regulated within a large scatter range in such a way that a predetermined beam current value is automatically set and kept stable.

Claims (6)

Patent claims: 1. Method of operating image pick-up tubes of the superorthicon type, the beam current of which is blocked periodically during the blanking time including the ramp-down time, thereby characterized in that the beam current is blocked only during part of the blanking time and at least during another part of the blanking time the storage electrode is applied in a manner known per se to a negative potential with respect to the beam cathode and that the direct voltage derived from the amplified output current of the image pickup tube is a the strength of the beam current significantly influencing electrode, preferably the Wehnelt electrode of the jet system, in the sense of an automatic stabilization of the jet stream will. 2. The method according to claim 1, characterized in that during the blocking of the Beam current, a pulse is added to the video signal at a suitable point, the amplitude of which is as follows is as large as the signal jump that occurs when the unmodulated beam current is blocked (suppressed) arises, its polarity with respect to the video signal being such that by the pulse a constant black level is generated, which is used as a reference value for clamping the video amplifier stages serves. 3. The method according to claim 1, characterized in that during the blocking of the Beam current, a pulse is added to the video signal at a suitable point, the amplitude of which is as follows is as large as the signal jump that occurs when the signal corresponding to the white level is blocked (suppressed) Beam current arises, so that a constant white level is generated by the pulse, which is used as a reference value for clamping the Video amplifier stages is used. 4. The method according to claim 1, 2 or 3, characterized in that the jet stream derived signal is picked up at the output of the secondary electron multiplier (6). 5. The method according to claim 1, 2 or 3, characterized in that the jet stream derived signal is picked up at the output of the preamplifier (11). 6. Circuit arrangement for performing the method according to claim 1, characterized by a peak rectifier, which is connected to the output of the secondary electron multiplier (6) or preamplifier (11) or signal picked up at another suitable point and its output via an amplifier stage (15) in such a way as to influence the beam current Electrode, preferably the Wehnelt electrode (4) of the cathode ray tube (1) connected so that the control voltage generated in the peak rectifier reduces the beam current as the signal amplitude increases. Considered publications:
German Auslegeschrift No. 1,077,251;
German patent specification No. 895 774. 1 sheet of drawings 409 597/167 5.64 © Bundesdruckerei Berlin