DE1036718B - Method of representing characters - Google Patents

Description

Method for representing characters The invention relates to a method to represent characters, e.g. numbers or letters, with the help of Cathode ray tubes produced Lissajouscher figures, parts of which passed through Light or dark control can be made visible. It is hereby pursued the purpose the representation of desired characters on cathode ray tubes with an opposite to achieve the known significantly reduced technical effort.

It is already known to place characters, particularly digits, on the screen image of cathode ray tubes. It is advantageous to use it as a basis for this a Lissajous figure with a frequency ratio of 1: 2. It has also already been proposed been able to change the basic curve of the Lissajous figure by suitable means. However, up to now all methods have required changes to the representation if the intention is to change them of characters three lines for horizontal and vertical deflection as well as for the dark control. This fact makes especially in extensive systems besides Numerous switching elements are still required for the aforementioned line expenditure.

The object of the invention is now the representation of characters in cathode ray tubes, in particular train numbers, to be carried out with a minimum of technical effort. According to the invention, this is done in such a way that periodic, z. B. trapezoidal Deflection voltages result in a basic Lissajous figure from which either, only with Help the Hell or. Dark control, a variety of characters such as numbers and letters are representable. The light and dark control pulses control the control grid and change the basic curve, for example a stylized "eight" in a desired manner.

The essential advantage given with the method according to the invention can be seen in the fact that by special means, namely deflection voltages, certain Form and frequency such an output curve is created, which, dark or When brightly controlled, only one single-core connection per tube is required. This simplification also results in a not inconsiderable increase in operational safety the plant. The invention is shown in the drawing, for example.

In Fig. 1, a stylized "eight" 1 a is shown, which results from the also shown, horizontally and vertically acting deflection voltage 1 b and 1 results in c. These are trapezoidal stresses, with the vertical effective deflection voltage 1 c between the positive and negative half-wave a Must have paragraph in which the voltage is zero. The frequency ratio the vertically acting to the horizontally acting deflection voltage is 1: 2, the absolute synchronization is due to the static doubling of the vertically acting Deflection frequency given. With the help of the known light and dark control the characters shown in FIG. 2, such as digits and letters, can be represented.

FIGS. 3 a and 3 b show two circuit arrangements which both the generation of the horizontally and vertically acting deflection voltages to serve. A circuit is used to generate the vertically acting deflection voltage 1 c according to FIG. 3 a. The line voltage U with the line frequency f1 is transformed to U2. The rectifier Gll receives a via the rectifier G14 and the capacitor Cl fixed direct voltage U4. A current only flows through resistor R1 when the amplitude U2 is greater than the DC voltage U4. Until the amplitude increases U2 to the level of voltage U4, the rectifier combination Gll has a very high great resistance.

The voltage (Ul + U3) occurring across the resistor R1 is shown in FIG. 4a. Resistor R2 is parallel to resistor R1, and rectifier combination G12 * Gl2 receives a fixed DC voltage U1 via G15 and C2. If the amplitude at R1 reaches the value of U1, the resistance for the part of the amplitude above U1 becomes U2 of G12. <R2. The voltage at R3 remains practically constant from this point on until the decreasing amplitude again reaches the value of U1 (FIG. 4a). Now the voltage at R3 changes just like the voltage at resistor R1. The desired curve shape for the vertical deflection thus drops off at R3 and is shown in Fig. 4a with a strong line. To generate the horizontally acting deflection voltage corresponding to 1 b, a voltage U with twice the frequency is transformed from f1 to U2 in accordance with the circuit in FIG. 3b. The functions of the components Gls, Gle, R4, R5 and C3 correspond to the functions of the elements G12, G15, R2, R3 and C2 of the generator for the vertical deflection voltage according to FIG. 3a. The voltage is shown in Figure 4b.

The DC voltages U1 and U4 of the generator for the vertical deflection voltage and the DC voltage U1 of the generator for the horizontal deflection voltage also, according to a further embodiment of the invention, by at the bridge points of the rectifier connected, parallel connected RC elements are generated, with the voltage level by choosing the resistor Re and the respective upstream resistors R1 or R2 is set. This measure eliminates both the transformer windings for U1 and U4 according to FIG. 3a as well as the transformer windings for U1 according to Fig.3b as well as the associated rectifiers and capacitors.

Claims (4)

PATENT ANSPR (J ('. HE: 1. Method for the representation of characters with the aid of Lissajousch figures produced in cathode ray tubes, parts of which are dark-controlled, characterized in that periodic, e.g. trapezoidal deflection voltages (1 b, 1 c) a Lissajousche basic figure (1 a.) Result, from which a variety of characters (Fig. 2) such as digits and letters can be displayed optionally, only with the help of the light or dark control. 2. Procedure according to Claim 1, characterized in that the horizontally and vertically acting deflection voltages result in a stylized "eight" (1 a). 3. Circuit arrangement for performing the method according to claim 2, characterized in that for generating the horizontally and vertically acting deflection voltages (Uv.A and Uh. A) voltages of normal mains frequency or double mains frequency (Uf, or Uf2) are used and that rectifiers preloaded with DC voltage in a bridge circuit (Gl1, G12, GI.) transform the required horizontal and vertical deflection voltage from the mains voltage (Fig. 2). 4. Circuit arrangement according to claim 3, characterized characterized in that the DC voltage required at the bridge points through a variable RC element is created.