DE1030472B - Circuit arrangement for controlling the brightness of a Braun tube - Google Patents

Description

GERMAN

The invention relates to a circuit arrangement for controlling the brightness of a Braun tube.

For example, in the case of display devices with a shiftable time base, it is often necessary to use a square-wave voltage with a variable duty cycle for light and dark scanning, since only the section of the beam path corresponding to the time base should be visible on the Braun tube. This problem has been solved in such a manner that, as shown in Fig. 1, inserted in the DC circuit between the cathode 1 and brightness control electrode 2 of a Braun tube, an ohmic resistor R, which has a capacity C, the light-dark Tastspannung U _T (t) is supplied. The direct current circuit between the electrodes 1 and 2 consists of the filter capacitor K, which is fed via a filter resistor R ' from a direct current source U _v , the voltage value of which can be freely selected by means of a potentiometer P. The touch voltage supplied to the resistor R via the capacitance C, the alternating current circuit of which is closed by the capacitance C ″, has, for example, the curve shown in FIG Voltage U is determined, the value of which is composed of the DC voltage U _g i occurring in the charging capacitor K and the mean value of the duty cycle U _1. If the duty cycle is changed, for example as shown in FIG is shortened, so is the mean value of U _t is increased (t), and the decisive for the brightness control voltage value U lowers. This results in a darkening of the image at unblanking or a lightening of the image at blanking. in addition occurs under certain circumstances an undesirable Change the sharpness of the image, since normally the favorable focusing of the electron beam can only be set for a certain beam intensity. All these properties of the known circuit are generally found to be troublesome, because they require readjustment of the individual setting elements of the circuit arrangement when the amplitude profile of the control voltage changes over time.

The present circuit is based on the task of showing a way that makes it possible to to get rid of these disadvantages.

In the present circuit arrangement for controlling the brightness of a Braun tube, in which a control voltage serving for brightness control is connected to the direct current circuit of the cathodes and brightness control electrode of the Braun tube
for brightness control
a Braun tube

Applicant:

Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Wittelsbacherplatz 2

Frido Weißker, Graefelfmg near Munich,
has been named as the inventor

is fed, should according to the invention in the direct current circuit of the cathode and brightness control electrode a directional conductor must be switched on, to which the control voltage is separated from the direct current circuit Capacitance or a transformer is fed. The guide can use a normal diode, in particular a silicon diode. The directional guide can, however, also be through a controllable electron tube or be replaced by a transistor, which is connected in the same way in the DC circuit are inserted.

4 shows the circuit arrangement according to FIG. 1 again, but with the insertion of a directional conductor G in place of the resistor R. The voltage divider in which the potentiometer P is located is at zero potential in a known manner with its other connection on high negative potential (- [/ „). An adjustable DC voltage U _{gl is} tapped via the potentiometer P , which is used as a bias voltage for the Braun tube with the cathode 1 and the brightness control electrode 2 via the sieve chain R ', K. The capacitance K is also connected to ground potential via the capacitance C ″ at the cathode-side connection. The sensing voltage U _T (t) is fed to the preceding control stage via C and the ground connection from the external resistance R _{a shown in dashed lines.}

The mode of operation of this circuit arrangement is such that when a sensing voltage of such polarity that the directional conductor G conducts is supplied, only the voltage U _g! of the capacitor K lies.

809 527/385

When the polarity of the probe voltage is reversed, however, the directional conductor G is blocked, so that practically the entire amplitude of the probe voltage at the directional conductor G drops. The direct voltage U _g i with the full amplitude of the sensing voltage is then located between the brightness control electrode 2 and the cathode 1 as the sum voltage. This case corresponds to the light control. By reversing the polarity of the directional guide G , the same mode of operation for dark control of the Braun tube results. The whole thing can be seen as a kind of clamping circuit. If necessary, it is advisable to connect a high-resistance resistor between electrodes 1 and 2 or in parallel with directional conductor G.

In FIGS. 5 and 6 it is shown how, for example, for light control even with a different duty cycle τ 1 / τ 2 because of the aforementioned property of the present circuit arrangement - due to the tip retention - the maximum values of the voltage between the brightness control electrode 2 and cathode 1 of the Braun tube always have the same high values.

7 and 8 show further exemplary embodiments in which the directional conductor G is inserted into the lead to the cathode 1 of the Braun tube. In this case it is advisable to put an ohmic resistor JS ″ (of, for example, a few megohms) parallel to the directional conductor G, which has a noticeably higher resistance than the directional conductor in the forward direction the Gleichstromzufluß is interrupted to the cathode 1 of the Braun tube in the blocking phase of the directional conductor G, particularly when using a SiIiziumdiode. Otherwise 4. operate the circuits substantially identical to the circuit of FIG. at low blocking resistance of the directional conductor G, z. B. when using a germanium diode - which generally has a blocking resistance of a few hundred kiloohms - the additional bridging resistor can be omitted.

In the circuits according to FIGS. 7 and 8, the directional conductor G can also be used to change the blanking mode the polarity of the circuit according to FIG. 4 is reversed.

Instead of the capacitive coupling of the control voltage U _T (t) , a transformer feed can in principle also be used, for example by connecting the secondary winding of the feeding transformer to the connections of the directional conductor (parallel connection).

Claims (2)

PATENT CLAIMS: 1. Circuit arrangement for controlling the brightness of a Braun tube, in which in the Direct current circuit of the cathode and brightness control electrode of the Braun tube one of the Brightness control serving control voltage is fed, characterized in that in The direct current circuit of the cathode and brightness control electrode is switched on by a directional conductor to which the control voltage is supplied via a capacitor or a transformer that is separate from the direct current circuit is fed. 2. Circuit arrangement according to claim 1, characterized in that when the Directional ladder into the cathode lead of the Braun tube of the directional ladder with one opposite the resistance of the directional conductor is bridged in the forward direction high resistance. 1 sheet of drawings © 809 527/385 5.58