DE755242C - Circuit arrangement for deflecting the beam in cathode ray tubes, in which the center perpendicular on the screen and the tube axis do not coincide - Google Patents

Description

In some types of cathode ray tubes, the cathode ray must be rectangular Swipe an area on a screen that is at an acute angle to the axis of the Device for generating the cathode beam is arranged. For example, should be mentioned be that in a television station cathode ray tubes are used, which have a mosaic screen and where the image to be transmitted is projected onto the same side of the screen as that of the cathode ray is scanned. if

the deflection of the beam bundle is accomplished in the normal way with sawtooth-shaped currents or voltages, the area scanned on the screen would be trapezoidal in shape. A circuit arrangement is known in which this is prevented in that the deflection for the individual lines takes place with a sawtooth deflection current, the amplitude of which changes in the course of the long flanks of the image or line extension deflection in such a way that despite the inclined position

of the screen on the same the lines are all written with the same amplitude. Furthermore, however, the scanned lines are also in the vicinity of those in this known case Edge of the screen that is farther away from the electron source than the other edge, farther apart.

The object of the present invention is to eliminate these disadvantages ίο In the case of a circuit arrangement for deflecting the cathode ray in cathode ray tubes, where the center perpendicular to the screen and the axis of the cathode ray tube do not coincide, by means of two tilting oscillations, one of which the beam parallel to that of the central beam axis containing plumb plane of the screen (image change or line change deflection) and the other in a direction perpendicular to it - (line deflection; distracts, .is therefore, according to the invention, the device device for generating vibrations for the first-mentioned deflection "such that the inclination of the current or voltage curve relative to the time axis increases, the closer the beam to the part of the screen that is closer to the electron source approaching. As already mentioned, the second oscillation is generally used for line deflection. In this case, the device for generating this deflection oscillation is according to a further aspect of the invention designed so that the amplitude of the row sawtooth changes with time so that the beam under the influence of the two deflections (line and image change or Line train change deflection) a rectangular area despite the inclination of the screen scans.

In the drawings, the subject matter of the invention is illustrated using a few examples and explained.

Fig. Ι shows a known circuit for generating sawtooth-shaped breakover voltages. The frequency of the generated oscillation is controlled by means of impulses running in one direction only, which come from a power source designated by 1. The duration of each pulse is very short compared to the intervals between the pulses. The anode-cathode path of the tube 2 is normally interrupted. A capacitor 3 is charged essentially uniformly via a resistor 4. The remote from the anode end of the resistor is held relative to the cathode of the tube at a fixed positive voltage "E If now a pulse impinges on the grid of the tube, it makes the mesh more positive;. Of the anode-cathode path of tube 2 is Then the capacitor 3 conducts and discharges. The charging and discharging of the capacitor 3 is then repeated periodically. The time constant of the circuit consisting of resistor 4 and capacitor 3 is usually large compared to the duration of the oscillation to be generated ". Those produced in this way ^; Vibrations are sawtooth-shaped tilting ■ vibrations of constant amplitude. Generators of this type are used for line deflection or for image change or line deflection.

For the following, it will now be assumed that the screen of a cathode ray tube to be scanned is arranged in such a way that the plane in which the undeflected beam and the vertical center line to be established on the screen lie extends vertically. In the schematic Fig. 2 , the screen seen from the side is denoted by 5, the cathode ray source by 6 and the direction of the undeflected cathode ray by o.

If a common electromagnetic or electrostatic deflector is used for the Movement of the beam is used to scan substantially horizontal lines the spacing between consecutive lines is not even. Of simplicity the screen is shown like this for the sake of it. as if it were only scanned with five lines would. The lines stand "perpendicular to the plane of the paper. It can be seen that the Line spacing in the vicinity of the screen edge 7, which is closer to the point 6, is smaller is as near the umbrella p.

Furthermore, instead of the dotted area shown in Fig. 3, the ray becomes a full one Scan lines drawn trapezoidal area. However, it is desirable that the .100 Ray scans a rectangular area and that the lines are equally spaced as approximately after Fig. 4 have. The sampling time is the same for each line. Therefore the newline deflection must of the beam close to the edge 7 in the angular dimension larger and close to the Edge 8 be smaller than that of the usual deflector. At the line deflection the amplitude must decrease when the beam moves from the edge 7 to the edge 8 emotional.

The desired deflection in the image height can take place by means of a tube with a normal deflection device in that the image change or line train change deflection oscillation is given a waveform as shown in FIG. Here the deflection voltage Ep (or current intensity in the case of an electromagnetic deflection device) increases more rapidly with small time values of t. at which the ray is in the vicinity of the edge 7, than at larger values of t, at which the ray is on

the one further away from the electron source Part 8 of the umbrella is located. The course of the sawtooth-shaped curve is then such that adjacent lines are equally spaced have from each other.

Furthermore can. it is arranged that the beam scans a rectangular screen area, by applying to the line deflection direction normal type, a voltage or current ¹

ίο from a course, as indicated by the dotted line 9 according to Fig. 6, is created. The deflection voltage E ₅ and the time t are entered here as coordinates. It can be seen that the frequency of the

! 5 oscillation according to Fig. 6 is constant and the amplitude decreases from the edge 7 to the edge 8. The envelope of the sawtooth-shaped oscillation 9 is formed by curves 13, the functions of the curve. Fig. 5 are. When using the deflection oscillations shown in Figs. 5 and 6, a screen that is perpendicular to the undeflected. Cathode rays Hegt (e.g. level 10 according to Fig. 2), a grid can be written as shown in Fig. 7. In contrast, a rectangular area is scanned on the screen 5, on which the adjacent lines have the same spacing. A generator according to Fig. 1 can have a wave shape according to Fig. 5 by appropriate choice of the values of the resistor 4 and the

'Generate capacitor 3. The time constant of the circuit, consisting of the resistance 4 and the capacitance 3, becomes. made smaller than that in the case where a substantially rectilinear wave shape is desired. The waveform 9 according to Fig. 6 is obtained as follows: If one does not allow a constant potential to act at point E in the circuit according to Fig. 1, but if the potential E ' present at this point according to the equation E' - K - _{kE F} runs, where K has a constant amount which is always greater than the subtrahend kEp (k is another constant), and if the capacitor 3 is completely discharged with each passage of current through the tube 2, the potential of the capacitor 3 at the moment can be represented by curve 11 in Fig. 6 prior to discharge. The wave generated therefore has the shape drawn in solid line at 12 in FIG. 6. Curve 9 is obtained by subtracting the curve, which is proportional to curve 11 and has half of the ordinate of curve 11 at each point, from curve 12.

A circuit that can be used to achieve this is shown in Fig. 8. A generator for pulses of image change or line change frequency 14 is with a tube 15, a capacitor 16 and a resistor 17 in the same way as parts 1, 2 3 and 4 connected according to Fig. 1. The time constant of capacitor 16 and des Resistor 17 is chosen in such a way that the vibration generated corresponds to that shown in FIG has time course. The vibration is amplified by a tube 18 and Terminals 19 fed to the (not shown) deflection device for the image or line train changes are connected. If the deflection is electromagnetic, so a corresponding circuit is provided in a known manner through which the voltage is so distorted at the terminals 19 that a current with the course after Fig. 5 flows through the deflection coils.

A line frequency pulse source 20 is connected to a relaxation oscillation generator according to FIG. 1, which has a tube 21, anode resistors 22, 23 and a capacitor 24. The tube 21 is coupled to a tube 25, between whose cathode and earth a resistor 26 is located. The cathode of the tube 25 is connected via a resistor 27 and a capacitor 28 to the control grid of a pentode 29, the output of which is connected via a transformer to the terminals 30 with the line deflection device of a cathode ray tube (not shown). The control grid of the pentode 29 is also connected via a capacitor 28 and a resistor 31 to an optionally variable tapping point of a resistor 32 between the cathode of the tube 18 and earth. A series circuit consisting of a capacitor 33 and a resistor 34 is connected in parallel with the resistor 32. An optionally variable tapping point of the resistor 34 is connected to the control grid of a tube 35, the anode of which is connected to the connection point of the resistors 22 and 23. The various points in the figure labeled -f- are connected to corresponding positive terminals of a voltage source (not shown), the negative terminal of which is grounded.

The potential E at the upper end of the resistor 22 thus has a constant component due to the direct voltage source, and also a variable component which is proportional to the respective value of the deflection voltage of the image change or line change frequency. The output voltage of the tube 21 will then have a time curve as shown by 12 in FIG. 6. The slope of the curve 11 can be changed by adjusting the tapping point on the resistor 34. The subtraction of a voltage, the time course of which is proportional to the time course shown (curve 11), from the voltage represented by 12

The oscillation set occurs by mixing (in resistors 27 and 31) the potential drop at resistor 26 with the potential drop at part of resistor 32 and by supplying the resulting oscillation to the control grid of the pentode 29. The resistors 27 and 31 are compared to the resistors 26 and 32 large. It can be achieved that the entrance of the Pentode 29 shows the course over time shown by curve 9 shown in dashed lines Has.

The shape of the voltage shown in FIG. 5 for the image change or line change can be regulated with the aid of a capacitor 36 of high capacitance without the amplitude of this oscillation being significantly changed as a result. This capacitor 36 is shown in dotted lines and is located between a variable tap point of the resistor 17 and earth. If the capacitor 36 has a sufficiently high value, * retains its remote from earth terminal a substantially constant potential, and the effective W ^r ert of the resistor 17 is connected between the anode of the tube 15 and the tapping point lying part. The amplitude of the oscillation for the line deflection can be varied by changing the potential applied to the upper end of the resistor 23, similarly the amplitude of the oscillation for the image change or line change deflection can be varied by changing the potential applied to the upper end of the resistor 17.

With the circuit shown in Fig. 8 it can be difficult or impossible in the coupling between the tubes 21 and 25 a substantial loss of low frequency Components of the signals going from the tube 21 to the tube 25 should be avoided. This Loss causes component distortion in the signals to be transmitted of the frame rate or line break frequency, d. h of the envelope 11 of the sawtooth oscillation 12. To remove or reduce this distortion, the in The circuit shown in Fig. 9 can be used.

In this circuit, a capacitor 37 is connected in series with the capacitor 24, namely the capacitor yj is connected between the assignment of the capacitor 24, which is not connected to the anode of the tube 21, and earth. The connection between the capacitors 24 and yj is connected to the control grid of the tube 25 and via a grid conductor 38 to earth. The resistor 26 in the Kathodenzuleittmg the tube 25 has a decoupling capacitor 39 in <shunt. The end of the resistor 27 facing away from the resistor 31 is connected to the anode of the tube 25. The tapping point at resistor 32 is connected to the grid of a three-pole tube 41 via a coupling capacitor 40, and a grid conductor 42 is located between the grid of this tube and earth.

In the input circuit of the tube 41, the time constant of the circuit consisting of the capacitor 40 and the grid lead 42 is essentially the same as that of the circuit consisting of the capacitor 37 and the grid lead 38 in the input circuit of the tube 25. The percentage loss of low-frequency components is therefore essentially the same in these two circles. The curve 13 (Fig. 6) and the envelope 11 of the curve 12 therefore receive essentially the same distortion. If these curves are subtracted from one another by connecting the output lines of the tubes 25 and 41 in the resistors 2y and 31, an essentially undistorted resultant according to curve 9 is obtained can be amplified without distortion. The waveform can be improved in these amplifiers by using negative feedback.

With cathode ray tubes of the type described above, it is often desirable to have a device through which the rectangular area scanned on the screen as a whole can be moved in directions parallel to two of its parallel sides. In the case of electromagnetic deflection, this can be achieved by having an adjustable DC component is superimposed on the currents of the deflection coils.

If the output stage of a sawtooth generator has an output transformer, the circuit according to Fig. 10 can be used. The output transformer 43 has a secondary winding with two identical coils 44, the outer ends of which via a transmission line 45 are connected to the deflection coils 46 of a cathode ray tube, which may have a mosaic screen, for example. This tube is about in a different place set up like the generators. A potentiometer 47 is via resistors 49, 50 of a power source 48 fed. The center 51 and a variable tapping point 52 of the Potentiometers 47 are connected to the inner ends of deflection coils 53 of a control tube. This can have a fluorescent screen so that the one scanned by the beam

Surface can observe. The outer ends of the coils 53 are with the inner ends of the Coils 44 connected. It can be seen that the potentiometer 47 and the deflection coils of the control tube with the center of the secondary winding of the transformer 43 are symmetrically connected. By adjusting the tap point · 52 am Potentiometer 47 can vary the strength of the direct current flowing through the coils 46 to change the position of the square field scanned on the screen. A same circuit can be in series with the output line of the other generator and the other pair of deflection coils to determine the position of the scanned field to move perpendicular to the aforementioned direction.

If no output transformer is used, the circuit according to Fig. 11 to be used. In this case the deflection coils 46 are at one end with the anode the output tube 54 and at the other end with a variable tapping point 55 one Potentiometer 56 connected. The> one end of the potentiometer is grounded, the other is connected to a terminal of the anode power source. A capacitor 57 is between the tap point 55 and earth. Adjusting the tapping point> 55 on the potentiometer 56 changes the strength of the through the Deflection coils 46 flowing direct current and shifts the Abtasifeld on the Umbrella.

Claims (4)

Patent claims: i. Circuit arrangement for deflecting the cathode ray in cathode ray tubes, where the center line on the screen and the axis of the cathode ray tube do not coincide, by means of two tilting oscillations, one of which contains the beam parallel to the one containing the central beam axis Plumb level of the screen (image change or line change deflection) and the distracts others in a direction perpendicular to it (line deflection), thereby characterized in that the means for generating vibration for the first-mentioned deflection is such that the inclination of the current or voltage curve in relation to the time axis becomes greater, the closer the beam is to the the part of the screen closer to the electron source. 2. Device according to claim 1, characterized in that the further Amplitude of the deflection voltage or deflection current generated for the second deflection (line deflection) over time changes in such a way that the beam under the influence of the two deflections (line and image change or line train change deflection) scans a rectangular area despite the inclination of the screen. 3. Circuit arrangement according to claims ι and 2, characterized in that that the sawtooth-shaped voltages for the line deflection generating tube has an anode voltage, which except one constant component a component of the frame rate or line break frequency which is derived from the voltage for the image change or line train change deflection and that of of the line deflection voltage of variable amplitude generated in this way, the direct current component by subtracting a likewise from the deflection voltage of the image change or line break frequency derived signal is eliminated. 4. Circuit arrangement according to claims ι to 3, characterized in that that the attenuation of the lower frequencies in the transmission channels leading to said subtraction point is kept approximately the same size. 90 To delimit the subject of the contract From the state of the art, the following publications are considered in the granting procedure been drawn: French patent specification No. 747 139, 762628, 762356, 762357, 762416;
British Patent No. 39g 654;
"Electrical communications engineering", 10, 1933, p. 215 ff .; "Television News", 1932, 174 to 176, 201/202. 1 sheet of drawings 3380 2.52