DE3921427C2 - - Google Patents

Description

The invention relates to a matching system for correcting Deflection errors in the deflection units of display tubes according to the preamble of claim 1.

As is known, in the deflection units of screen tubes Deflection errors occurring, visually recognizable by the image geometry drive formed from the deflection unit and screen tube corrected. Such errors lead to Ab, for example deviations from orthogonality, to asymmetries, or trapezoid, pillow or barrel shaped distortions. causes for this, the presence of non-right-angled ones can be used Deflection unit field coils, ferromagnetic properties of the coil material used, or the winding arrangement or be winding symmetry.

Depending on the error and tolerance, correction magnets are under different field strength attached to the deflection unit, wherein the magnets are releasably attached, for example by Ver use of grub screws. The adjustment is done manually carried out until the error is compensated, which one means considerable effort.

A circuit arrangement for the automatic correction of the Lichen pillow distortion in color television receivers, in particular in beam switching television receivers, is from DE 30 22 496 A1 known. One becomes in addition to the main horizontal deflection coil existing correction horizontal deflection coil one out of two Signals pulse generated by amplitude modulation only the side pillow distortion.  

The arrangement has several switching strips on one Part of the screen are arranged horizontally, and a photodetector for determining the scanning on a Toggle strips through an electron beam.

A sensor system for automatic adjustment of the deflection system of television picture tubes is also from EP 01 35 642 A1 knows. This adjustment system is also used to eliminate spe distortion, here the east / west and pillow distortion To avoid a linear sensor, a rectangular frame made of a striped arrangement of alternating radiation-permeable and beam opaque segments formed. The arrangement can either placed on the inside of the screen or on its outside be applied. The measuring sensors are there executed in one dimension.

The present invention has for its object an Ab to design the same system of the type mentioned at the beginning, that a correction of all kinds of distortions he can follow without the need to grasp the image geometry agile sensor system can be arranged on or in the screen got to.

The solution to this problem is given by the characteristic note male of claim 1 reached.  

The polarity correctly integrated in the deflection unit Magnetized correction magnets offer the advantage that the distinguished by changing the correction magnets several times operations occurring during the field strength can. Another advantage is that the measuring sensors for capturing the image geometry from the screen on a mask are arranged, with the arrangement of one-dimensional Measuring sensors on lines of symmetry and of two-dimensional Measuring sensors in the corner points a scan of the entire image screen and not just a screen section becomes. A weakening of the too strong mag Netization for the rigid correction magnets is achieved through an adjustment causes energy that depends on using the sensors delivered measured values can be adjusted.

According to a development of the invention, the weakening achieved by building an opposite polar magnetic field, which of a capacitor bank with variable storage energy becomes. This has the advantage that the magnets are too weak can be magnetized again by reversing the polarity of the magnetic field can.

According to another development of the invention, the Schwä achieved by applying an alternating magnetic field be, which enables a much more sensitive adjustment light.

Details of the invention are based on one in the drawing illustrated embodiment explained in more detail.

In detail show:

Fig. 1 is a deflection unit with the correction magnets of a known type,

Fig. 2 shows the deflection unit of Fig. 1 according to the invention arranged correcting magnets,

Fig. 3, the entire alignment system for the correction of deflection errors, and

Fig. 4 shows the arrangement of the measuring sensors.

Fig. 1 shows a deflection unit A of a known type, which has current-carrying deflection coils AS for generating a magnetic field. If distraction errors occur, they can, for example, result in distortions. To eliminate this, correction magnets KM are releasably attached to the outside of the deflection unit A, for which purpose grub screws GS are used. The adjustment takes place by repeated manual attachment of magnets of different field strengths until the error is compensated for or is within predetermined tolerances.

In contrast to the illustration in FIG. 1, the correction magnets KM are integrated into the deflection unit A according to FIG. 2, the magnets being magnetized with the correct polarity, for example to generate a magnetic opposing field to weaken an excessive magnetic field strength.

The deflection unit A provided with the correction magnets forms, according to FIG. 3, together with the display tube BR and the screen S the unit ME, which is adapted to scan an image pattern, a mask M emulating the screen geometry. In this mask shielding stray light, sensors are integrated, the analog measured values of which are acquired synchronously with the image pattern by a transducer UE and are fed to an evaluation unit AE, for example in the form of a control computer.

An opposite pole magnetic field with variable field strength is there generated by that a capacitor bank with a voltage is loaded, the value of which depends on the deviation of the ver measured image pattern to a standard image from the evaluation unit AE is determined and passed on to a setting unit EE. The adjustment unit EE then provides the necessary adjustment energy to weaken the field strength of the correction magnets in the unit ME. The discharge of the charged capacitor battery takes place via an air coil.

The arrangement of the sensors as a measuring sensor is shown in FIG. 4. Darge represents a cushion distortion KV, which can be detected on the basis of the one-dimensional sensors SLS used in the lines of symmetry and the two-dimensional sensors EPS provided at the corner points. The number of sensors per line of symmetry depends on the accuracy of the measuring system.

Claims (3)

1. Adjustment system with several correction magnets (KM) under different field strengths for correcting the deflection errors occurring in the deflection units (A) of screen tubes, as well as with measuring sensors (SLS) for detecting the image geometry from the screen (S), characterized in that

• - that the correction magnets (KM) are magnetized with correct polarity in the deflection unit (A),
• - That a mask simulating the screen geometry (M) is arranged in front of the screen (S) in which one-dimensional measuring sensors (SLS) are each integrated on lines of symmetry and two-dimensional measuring sensors (EPS) in the corner points, and
• - That, depending on the measured values supplied, a balancing energy causing a weakening of the field strength of the correction magnets (KM) is provided by an adjusting unit (EE).

2. matching system according to claim 1, characterized, that the field strength of the correction magnets (KM) by applying one from a capacitor bank with variable memory energy generated, opposite polar magnetic field is reduced. 3. matching system according to claim 1 or 2, characterized, that the field strength of the correction magnets (KM) by applying of an alternating magnetic field is weakened.