DE10140038A1 - Method and circuit arrangement for operating a monochrome cathode ray tube at a predetermined cathode operating point - Google Patents

Abstract

The invention relates to a method and a circuit arrangement for operating a monochrome cathode ray tube at a predetermined cathode working point. Said method and circuit allow a relatively good consistency of luminance to be rapidly achieved.

Description

The invention relates to a method according to claim 1 and a circuit arrangement according to claim 6 for operating a a cathode, a control grid and an acceleration grid having a monochrome cathode ray tube in one predetermined cathode operating point, at which or by means of which the working point by a voltage at Acceleration grid is set, being in predetermined Time intervals for regulating the cathode current to the cathode Reference signal is applied, and the voltage at Acceleration grid is changed until the cathode current a predetermined value corresponding to the reference signal has reached.

The disadvantage of cathode ray tubes is that their Luminance changes during a warm-up phase, i. H. the time until the cathode ray tube achieves its thermal stability has changed a lot. The warm-up phase of a usual The cathode ray tube can be up to twenty minutes. For example, during the warm-up phase Luminance values overshoot of up to 100%.

The height of the overshoot and the time of the warm-up phase is also dependent on whether the cathode ray tube is longer Time was off. So it is for the amount of Overshoot as well as for the time within which the Cathode ray tube has reached its thermal stability, from of great importance whether the cathode ray tube lasts several hours was off or just a few minutes or seconds.

In cathode ray tubes used as picture tubes, it is known, in particular in the case of higher-quality monitors, for Keeping the luminance constant or accordingly A so-called cutoff point control perform. With the cutoff point control the monitor at the time of regulation by setting to one Reference brightness brought into a defined measurement state. For this, a defined one is defined between the cathode and the control grid Voltage applied, which a certain Reference luminance results. The voltage on the acceleration grid is then changed until the luminance of the Reference luminance respectively, because of cathode current and luminance behave proportionally to each other, the cathode current corresponds to a corresponding reference value.

Because the thermal stability of for the invention provided monitors can be described as very good Cutoff point control in continuous operation about every twelve hours carried out. Because of the thermal instability during the Warm-up phase of the monitor becomes a cutoff point control not carried out during the warm-up phase. The first Cutoff point control is carried out after the warm-up phase, i.e. H. to about twenty minutes.

The implementation of a cutoff point regulation is under Circumstances with interference for the user of the monitor connected because a target brightness is set for the measurement becomes. The target brightness differs from the current one set brightness, this becomes visible, so that the current Image has interference. Furthermore, depending on the video Timing the displayed measurement line will be visible in the image. In addition, it is disadvantageous that only twenty minutes after switching on, d. H. after the first Cutoff point control, the guaranteed brightness and contrast values can be reproduced.

A cutoff point control and thus is particularly disadvantageous a change in luminance during the warm-up phase for monitors that are in a so-called energy-saving mode can walk; because after activating the Cathode ray tube after every "Suspend" or "Sleep" state must be about wait twenty minutes for the luminance and hence the brightness and contrast a stable state have reached after a new cutoff point regulation.

It is an object of the invention, one mentioned Method and a circuit arrangement mentioned at the outset to train in such a way that after a short time a relatively good one Constancy of the luminance is achieved.

The solution to this problem results from the features of characterizing part of claims 1 and 6. Advantageous Further developments of the invention result from the Dependent claims.

According to the invention is a method for operating a a cathode, a control grid and an acceleration grid having a monochrome cathode ray tube in one predetermined cathode operating point at which the Working point by a voltage on the accelerating grid is set, at predetermined time intervals for Regulation of the cathode current to the cathode Reference signal is applied, and the voltage across the Acceleration grid is changed until the cathode current a predetermined value corresponding to the reference signal has reached, characterized in that at the first Regulation of the cathode current after activation of the Cathode ray tube attached to the accelerator grille Reaching the predetermined value of the cathode current applied voltage with the last one before the deactivation of the Place the cathode ray tube on the acceleration grid Voltage is compared and that on the acceleration grid applied voltage to the after a predetermined function last on the cathode ray tube before deactivation voltage applied to the accelerating grid becomes.

Furthermore, according to the invention is a circuit arrangement for operating a cathode ray tube with a cathode, a control grid and an acceleration grid at one specific cathode operating point, which is a timer has, for the repeated initiation of a setting of Cathode current characterized in that a first Memory is available for storing the on the acceleration grid applied voltage value according to the last one set cathode current.

The fact that the first control of the cathode current on the acceleration grid when the predetermined one is reached Value of the cathode current applied voltage with the last voltage applied to the acceleration grid and the voltage applied to the acceleration grid after a predetermined function to the last on the Accelerating grid applied voltage is adjusted, high constancy of luminance can be easily achieved Reach wise after a very short time; because by that at the first regulation of the cathode current on the Acceleration grid when the predetermined value of the Voltage applied to the cathode current with the last one at the Accelerating grid applied voltage is compared it is determined how large the deviation of the on the Acceleration grid applied voltage from the voltage in the steady state is. This deviation will then to about zero within twenty minutes reduced.

The invention makes use of the knowledge that the Setting a specific working point on the Acceleration grid required in the steady state Voltage after reactivating the cathode ray tube is constant. Thus, the tension on Acceleration grid for a certain working point in the steady state State can be predefined.

The first regulation of the Cathode current immediately after reactivation the cathode ray tube. Through the regulation one gets immediately after activation of the cathode ray tube Voltage value to which the voltage on the acceleration grid must be set so that a cathode current accordingly the predetermined cathode operating point and thus flows according to the brightness reference signal. Starting from this voltage value applied to the acceleration grid the voltage on the acceleration grid is reduced to that in the steady state required voltage lowered.

The lowering happens advantageously after one e-function, where the exponent of the e-function is t / TAU, where t is the time in seconds and the value TAU is about 120 is. This brings the tension closer to Acceleration grid in an optimal way to the value that they in steady state. With such a Approach is advantageously achieved after overshoot occurring in the first cutoff point regulation Range of less than 3%.

An embodiment of the Invention highlighted in the adjustment residual amounts be added and when a full value of the current value is increased by one in order to readjust to be considered; because those for setting the predetermined value of the cathode current required voltage at Acceleration grids can be used in a digital Do not always implement signal processing exactly as the smallest Voltage change depends on the number of bits with which the voltage value is displayed. Therefore, on Accelerator grid applied voltage of the required Follow the tension. This would result in a minor Displacement of the cathode current result, whereby the correct luminance value before regulation in thermally stable Condition is not reached.

The remaining amounts are advantageously combined in one saved second memory, as in another special embodiment of the invention is provided.

If the corresponding remaining amounts are added until they give a value that matches the last significant bit is presentable, d. H. give the smallest value by which the Voltage on the acceleration grid can be reduced this value will be taken into account in the next setting. This means that the voltage on the acceleration grid is thereby reduced set to their current setpoint. Thus in advantageously achieved that when setting the Voltage on the acceleration grid not realizable Voltage drops are not lost.

Further details, features and advantages of the present Invention result from the following description of a particular embodiment with reference to the drawing.

The only figure shows a schematic representation a block diagram of an inventive Circuitry.

As can be seen from the figure, a monochromatic cathode ray tube 4 has a cathode 3 , an acceleration grid 2 and a control grid 1 . This corresponds to the conventional structure of a cathode ray tube.

The voltage on the acceleration grid 2 can be used to set the cathode current and thus the intensity of the cathode beam and thus indirectly the brightness of the picture tube.

A video signal 11 to be displayed on the cathode ray tube 4 is first fed to a video amplifier 10 . The video amplifier 10 contains a cathode current detection unit 8 and a measurement signal generation unit 9 . The outputs of the video amplifier 10 are connected to the cathode 3 and the control grid 1 .

Furthermore, there is an evaluation unit 14 which has a timer 5 , an arithmetic unit 12 and an actuating unit 7 . The output of the actuating unit 7 is connected to the control grid 2 . The input of the actuating unit 7 is connected to the output of the arithmetic unit 12 . Furthermore, a first memory 6 and a second memory 13 are connected to the arithmetic unit 12 . A first output of the timer 5 is connected to the measurement signal generating unit 9 , a second output to the arithmetic unit 12 .

After switching on or after activation of the cathode ray tube 4 , the timer 5 activates the measurement signal generating unit 9 so that it outputs a measurement signal to the cathode 3 of the cathode ray tube 4 . The corresponding cathode current is measured by means of the cathode current detection unit 8 . The measured value is communicated to the arithmetic logic unit 12 . The arithmetic logic unit 12 causes the control unit 7 to change the voltage on the acceleration grid 2 until the cathode current has a size corresponding to the signal emitted by the measurement signal generation unit 9 , ie the cathode current corresponds sufficiently precisely to a stored target value while the measurement signal is present.

If the cathode ray tube 4 is at its operating temperature, the voltage output by the actuating unit 7 to the acceleration grid 2 corresponds to the operating point of the cathode ray tube 4 . This value is stored in the first memory 6 after each adjustment of the voltage on the acceleration grid 2 .

Since the cathode ray tube 4 is not at its operating temperature when the cathode ray tube 4 is switched on or activated after a more or less long rest, the voltage required on the acceleration grid 2 to achieve a measurement signal corresponding to the measurement signal generation unit 9 is different than the voltage which is required on the acceleration grid 2 after the operating temperature of the cathode ray tube 4 has been reached, ie as the voltage which is stored in the first memory 6 .

According to the invention, after the cathode ray tube 4 is switched on or activated, the voltage required on the acceleration grid 2 is compared with the value stored in the first memory 6 . The difference determined by the arithmetic unit 12 is brought to zero in the course of about twenty minutes in accordance with a table stored in the first memory 6 . D. h., The voltage at the accelerating grid 2 according to the stored in the first memory 6 Table from its initial value to the last before the switch-off or prior to the reconnection or re-activation of the cathode ray tube 4 adapted to 6 memorized value in the first memory. The adaptation is done at time intervals which are communicated to the calculating unit 12 from the timer. 5 The table is designed so that the adaptation takes place in the form of an e-function.

Since the setting unit 7 is implemented digitally, the voltage delivered to the acceleration grid 2 does not always have the exact value that it should actually have. This often results in a deviation of the cathode current from its required value. The residual amounts of voltage at the acceleration grid 2 causing this are stored in the second memory 13 . If the values stored in the second memory 13 reach a value which corresponds to the smallest voltage change that can be output by the setting unit 7 , the value stored in the second memory 13 is taken into account when the voltage on the acceleration grid 2 changes again. A very precise adjustment of the cathode current is hereby achieved.

Claims (8)

1. A method for operating a cathode ( 3 ), a control grid ( 1 ) and an acceleration grid ( 2 ) having a monochrome cathode ray tube ( 4 ) at a predetermined cathode operating point, at which the operating point is set by a voltage on the acceleration grid ( 2 ) is, where a reference signal is at predetermined time intervals to control the cathode current to the cathode (3) is applied, and the voltage to the accelerator grid (2) is changed until the cathode current one corresponding to the reference signal predetermined value has reached, characterized in that that in the first regulation of the cathode current after activation of the cathode ray tube ( 4 ), the voltage applied to the accelerating grid ( 2 ) when the predetermined value of the cathode current is reached is compared with the last voltage applied to the accelerating grid on the cathode ray tube ( 4 ) prior to deactivation , wobe i the voltage applied to the accelerating grid ( 2 ) is adjusted according to a predetermined function to the last voltage applied to the accelerating grid on the cathode ray tube ( 4 ) before deactivation. 2. The method according to claim 1, characterized in that the first regulation of the cathode current takes place immediately after the activation of the cathode ray tube ( 4 ). 3. The method according to claim 1 or 2, characterized characterized in that the predetermined function is an e-function is. 4. The method according to claim 3, characterized in that the exponent of the e-function is t / TAU, where t is time in seconds and the TAU value is approximately 120. 5. The method according to any one of claims 1 to 4, characterized characterized that add-on residual amounts are added and the current one when a full value is reached Value is increased by one. 6. Circuit arrangement for operating a cathode ray tube ( 4 ) with a cathode ( 3 ), a control grid ( 1 ) and an acceleration grid ( 2 ) at a specific cathode operating point, which has a timer ( 5 ) for the repeated initiation of a setting of the cathode current, characterized in that a first memory ( 6 ) is provided for storing the voltage value applied to the acceleration grid ( 2 ) in accordance with the last set cathode current. 7. Circuit arrangement according to claim 6, characterized in that an actuating unit ( 7 ) is provided, the input of which is connected to the output of the first memory ( 6 ) and the output of which is connected to the acceleration grid ( 2 ) and which is in the first memory ( 6 ) converts stored values into a voltage and outputs it at its output. 8. Circuit arrangement according to claim 7, characterized in that a second memory ( 13 ) is present, in which the control unit ( 7 ) unreachable residual voltage amounts are stored.