DE3732002A1 - Colour television projection device with automatic correction of picture geometry and colour convergence - Google Patents

Abstract

Television projection with three separate picture tubes gives rise to the problem of bringing these three partial images precisely into a congruent position on the screen. In the normal case, this can be achieved only by laborious manual setting. To be able to influence the geometrical properties of the projected partial images, for each picture tube there are used not only the necessary main deflection coils but also additional corrective deflection coils, the magnetic field of which is superimposed on the main magnetic field. The automatic measurement of the geometry of each individual projected chromatic component permits the calculation of errors, which can be used for an automatic correction of the picture geometry. By using novel circuitry, the influencing of the geometry takes place exclusively by means of the in any case existing main deflection coils; auxiliary deflection coils are not required. The generation of the necessary correction signals is possible by means of a digital memory, which is read out synchronously with the picture build-up and the output signal of which passes through a digital-to-analog converter. The invention has applications in television technology. The circuitry used for the horizontal deflection can, in addition, be employed in electron microscopy and electron-beam lithography.

Description

The invention relates to a color television projection device automatic correction of image geometry and color convergence.

In the claimed color television projection device is by Measurement of the current geometry distortion of each individually projected Color separation won an error size. By converting this size into Correction parameters can be adjusted using suitable deflection circuits Readjust the geometric shape of the individual drawing files until color convergence and image geometry achieve the required quality.

It is known that magnetic deflection in electrons beam tubes geometric image distortions arise, their nature and out measured by the course of the magnetic field causing the deflection  becomes. Treatises for this can be found in "Zeitschrift für Physik", year 1941, volume 118, pages 593 to 617, further in "Zeitschrift für Physik", Year 1942, volume 119, pages 423 ff. Works on the same subject lie gen in "Philips Research Report", year 1957, volume 12, pages 46 to 68 and "Philips Research Report", year 1959, volume 14, pages 65 to 97, in front.

In the case of color television image projection with three separate, the primary colors The projection direction is red, green and blue picture tubes of the three systems not the same, because the individual color separations are geometrical different locations are generated, but precisely in the image plane Cover must be brought. To correct the resulting Oblique projection distortions can result in prismatic tube attachments be set ("IEEE Spectrum", year 1981, issue 11, pages 40 to 45).

Methods are known which partially address the image errors mentioned to lift. These include the "East-West" applied in color television technology. Correction "and the elimination of the" tangent error ".

However, the correction devices mentioned are not able to especially the distortions that occur in color television projection to eliminate a single measure. Therefore, in this area Often additional correction deflection coils are used which create a magnetic field testify that overlaps the field generated by the main deflection coil.

For automatic convergence correction in color television playback with Pinhole picture tube is a method known in "IBM Journal of Research and Development ", Vol. 24, No. 5, Sept. 1980, pages 598 to 611. However, the technology used there is not up the projection of television images applicable.

The invention has for its object the correction of the geometri distortions and the convergence error of projected color television perform images completely automatically; on additional auxiliary steering coils should be avoided.

This object is achieved in that by measurement the current geometry of each individually projected color separation is a mistake size is obtained with which the geometry of each individual image can be adjusted. To avoid additional correction deflection coils  the deflection currents with the help of suitable circuit technology correction signals superimposed, which contain both DC and AC components can. The correction signal of each individual deflection is one Function of the two coordinates of the image location.

To obtain the required correction signals, the geo every single projected color separation. To this end an image signal is generated by a test image generator included in the device delivers, which consists of light lines on a dark background. With help this test pattern becomes the actual location of a series of pixels determines whose position within the test image is known exactly. From the This location information can be used to calculate geometry features that describe existing geometric nonlinearities and deflections ben.

In order to geometrically equalize the individual images, the electron beam must be deflection each picture tube generate a grid, its electronic ent distortion is inverse to the measured image distortion. For this, the normally sawtooth-shaped components of the horizontal and vertical deflection currents superimposed on correction portions from image location to Image location vary.

A new type of horizontal deflection circuit is used for the technical implementation of this equalization in the horizontal direction without the use of correction deflection coils, the basic circuit diagram of which is shown in FIG. 1. The switch required for the deflection is represented here by the transistor T and the return current diode D. A pair of thyristors with a commutation network could also be used instead.

In the same way, as is already known from television technology, the transistor T is switched periodically by the control current I _B into the conductive and blocked state, the blocking initiating the line return. The capacitor C _A together with the deflection coil L _A forms a parallel resonance circuit which determines the return speed. The return is terminated by the diode D , which takes over the deflection current during the first half of the forward. During this time, the control current I _B must switch the deflection transistor back into the conductive state.

For the explanation of the effect of the correction voltage U _{K, it} is initially assumed that the deflection coil L _A has no ohmic winding resistance. Since the deflection works periodically, the integral of the voltage across the deflection coil results

ie the time average of the voltage U _K is equal to the time average of the voltage U _A. With this reasoning it follows that the time average of the voltage at R _{H has} the same value. Accordingly, the average current I _H (averaged) = U _K (averaged) / R _H flows through the auxiliary inductance L _H. If the time constant L _H / R _{H is} dimensioned sufficiently large, this current is not subject to any significant short-term fluctuations. Since the deflection current I _A from the sum of the transistor current I _T and the auxiliary current I _H is, thus, can achieve a ho zontal displacement of the deflection region. However, this shift can change slowly, so that an individual influence of the beginning and end of the picture is possible.

Is averaged over a deflection period value of U _K equal to zero, the instantaneous value of U _K during the line trace but from zero ver secreted are deflection amplitude and linearity affected because at this stage of the deflection coil, the sum of the operating voltage - U _B and the correction voltage U _K is present.

The deflection coil L _A actually has a noticeable ohmic resistance. However, this affects essentially only the DC component of the correction current and requires that the correction voltage U _K (averaged) required to achieve a certain image shift must be increased in the ratio in which the winding resistance to the resistance R _H is.

The voltage U _K is supplied by a power operational amplifier, which is supplied by the zero-symmetrical operating voltages + U _V and - U _V.

Fig. 2 shows the specialization according to independent claim 4. The individual deflection circuits are decoupled by the diodes D _{E 1} to D _{E 3} .

The correction of the vertical variables takes place in a relatively simple manner kung. Here the output signal of a correction signal generator becomes direct led to the deflection coil, since the correction signal generator both the Sawtooth portion as well as the correction components.

The advantages achieved with the invention are in particular that to project one of geometric distortions and color divers limits free color television picture no manual adjustment is required. The technical effort to achieve the required deflection geometry remains relatively low because of the circuit used technology for each picture tube only one pair of deflection coils, each consisting of one Horizontal and a vertical deflection winding is required. Additional Correction deflection coils are not required. A repetition of the Cor rectification process is only to compensate for component aging or after a Transport required.

In addition to its use in television technology, the process offers a Possible uses in all areas in which electron beam deflections are required, for example in electron microscopy and elec electron beam lithography.

An embodiment of the invention is explained below with reference to the block diagram Fig. 3.

Due to the intended application, the sample device for a refresh rate of 50 Hz and a line frequency of 15 625 Hz designed; apart from the missing interlacing and the result of it giving the number of lines of 312.5 corresponds to the CCIR standard. The device is is also able to process standard television signals, but writes the two fields one above the other without interlacing.

The video fed separately for the red, green and blue channels The three video amplifiers control the brightness of the signals used dete picture tubes. The CCIR sync signal is via another input supplied, but can also be superimposed on the video signals. The circuit to separate the synchronous signal from the video signals is the state of the art Technology and was not shown for reasons of clarity.

The horizontal and verti separate synchronous components. These two components serve two  digital counters exactly at the beginning of a picture or line To set zero. In the vertical part this happens with a direct back Set command to the vertical counter, a PLL (phase locked loop) synchronized, whose oscillator with an integer multiple Chen the horizontal deflection frequency swings.

The status of the vertical counter is the address for the following corrections door memory and determines the TV to be written row. The position within the line is determined by the horizontal counter that generates the least significant bits of the memory address. To Memory addressing is used for 9 bits vertically and 4 bits horizontally. The number the horizontal bits appear very small; but it could be shown that by linear interpolation between the 16 correction values one out sufficiently precise distraction is possible. The interpolation is carried out by the Horizontal deflection coil itself, the current of which is applied Tension according to a bottleneck function follows.

The information in the three correction memories has a resolution of 12 bits in the vertical part and 10 bits in the horizontal part. It is carried out by means of the generated address signals read out and the digital-to-analog converter Deflection circuits supplied.

The current geometry is measured in the sample device with the help of 13 photodiodes made. These are on a plate attached to the Place the canvas can be pivoted into the image plane. A test image generator creates bright lines with vertical or horizontal orien tion that slowly sweeps over the measuring plate and thus an exact er enable averaging the position of the photodiodes relative to the television picture. The Information obtained is recalculated by a Z80 microcomputer who uses correction memory contents.

Claims (7)

1. Color television projection device with automatic correction of image geometry and color convergence, constructed with three separate picture tubes for the reproduction of the individual color separations, which are projected onto a common screen, characterized in that the automatic adjustment is done by a control loop, which on the one hand is a method for measurement the actual image geometry and on the other hand includes a device for influencing the image geometry. 2. color television projection device according to claim 1, characterized in that by special circuit technology line by line structure of the individual television pictures and the influencing the image geometries with a single pair of deflection coils per picture tube is made possible. Additional correction deflection coils are not required Lich. 3. color television projection device according to claims 1 and 2, characterized in that for the correction of all horizontal geometry error a new deflection circuit is used, the exp the conventional transistor or thyristor deflection stage represents a correction signal generator and an auxiliary inductor. With this arrangement becomes a deflection current with a sawtooth Basic component and additional equal and alternating components for Geo gear influence generated. 4. Color television projection device according to one or more of the An sayings 1 to 3, characterized in that with the synchronous operation of several picture tubes only a conventional deflection stage in the horizontal deflection is required is such. The individual correction of each image is carried out using a assigned correction signal generators and auxiliary inductors.   5. Color television projection device according to one or more of the An sayings 1 to 4, characterized in that the generation of the correction signals by means of a digital memory, the content of which is read out synchronously with the image and via digital-analog converter with subsequent power amplifiers is fed to the deflection circles. 6. Color television projection device according to one or more of the An sayings 1 to 5, characterized in that determined to measure the image geometry is what points of the television picture on selected locations of the Image plane can be projected. This orientation is for a number performed by pixels. 7. color television projection device according to one or more of claims 1 to 6, characterized in that the deflection mentioned in claim 3 circuit also in television camera technology, electron microscopy and electron beam lithography can be used.