JPH10503350A - Improvement of brightness uniformity on display screen - Google Patents

Abstract

(57) [Summary] The method of the present invention is to reduce the decrease in the amount of light in the edge direction of the display screen (10) of the display tube (1). The extent of the decrease in the amount of light depends in particular on the change in the glass thickness of the display screen (10) from the center to the edge of the display screen (10), and on the transparency of the glass. In the present invention, this decrease in light quantity is corrected by decreasing the deflection speed from the center of the display screen (10) toward the edge (C1, Cs).

Description

DETAILED DESCRIPTION OF THE INVENTION                   Improvement of brightness uniformity on display screen   The present invention improves the brightness uniformity on the display screen of a display tube provided with a control electrode. And a correction circuit. This method converts the control electrode to an image signal. Responsively driving to generate a modulated electron beam; Deflecting the image signal to display an image signal on a display screen.   The present invention also relates to a display device provided with such a correction circuit.   A display screen for displaying an image signal, an electron gun for generating three electron beams, and Deflection units that generate horizontal and vertical deflection magnetic fields that deflect these electron beams An image display device provided with a color display tube having the same is generally known. 3 electronic web The beam forms a combined electron beam together and the display screen is controlled by the deflection unit. Draw a line on the lean. The three electron beams are modulated by image information and displayed The amount of radiation at each position in the scene. This amount of light per second at a given position Especially affected by the amount of electrons in the composite electron beam (commonly called beam current value) Is done. Such known display devices have a light intensity approaching the edge of the display screen. The disadvantage is that the brightness uniformity on the display screen is disturbed. Display The decrease in brightness along the edge of the screen is especially noticeable from the center to the edge of the screen. Caused by the increasing thickness of the display screen glass. This decrease in light intensity is As the transmission of the glass decreases to improve the black level on the display screen It becomes more and more prominent. This disturbed brightness uniformity is especially true when the electron beam is It is visually annoying when the lean is modulated to write with a constant beam current. You.   It is an object of the present invention to provide a method and a correction circuit for improving the brightness uniformity on a display screen, Another object of the present invention is to provide an improved display device.   To this end, a first feature of the invention is a luminance uniformity as claimed in claim 1. In which the image signal is converted to the aspect ratio of the display screen. And the deflection speed of the modulated electron beam is displayed. Controlling the deflection to decrease from the center of the screen to the edge. It is characterized by This point depends on the deflection speed (the electronic beam traversing the display screen). Of the display screen so that the optimal geometrical shape of the display information is obtained. This is completely different from a normal display device which is as constant as possible over the entire area.   A second aspect of the present invention is a display device for improving luminance uniformity according to claim 6. And the display further increases the deflection speed of the electron beam with improved brightness uniformity. To reduce the distance from the center to the edge of the display screen to obtain It is characterized by having a step.   A third feature of the present invention is a correction circuit according to claim 8.   A fourth aspect of the present invention resides in a method according to claim 9, further comprising: The deflection speed of the modulated electron beam in at least the line direction is Control the deflection to decrease from the center to the edge, at least one frame position Comprising a step of substantially compensating for a decrease in light output in the line direction at And   A fifth aspect of the present invention resides in a method according to claim 10, wherein the method comprises: In addition, at least the deflection speed of the modulated electron beam in the line direction is determined by the display screen. Controlling the deflection to decrease from the center of the image to the edge; and Controlling the instant of occurrence of the image so as to reduce the position error on the display screen. Characterized by having   Advantageous embodiments of the invention are set out in the dependent claims.   Such a method for improving the brightness uniformity on the display screen is based on the fact that the amount of emitted light is It is based on the recognition that it depends on the deflection speed of the system. Practically slow deflection speed The higher the number of electrons per second that hits a given position on the display screen, The amount of light increases. Electron beam deflection speed decreases towards the edge of the display screen Light that decreases towards the edge of the display screen by controlling the deflection The amount can be completely or partially compensated.   The present invention reduces the amount of light in the edge direction of the display screen by increasing the beam current. It is suitable to reduce without. Therefore, the spot size of the modulated electron beam is No adverse effects.   From EP-A-0,567,301, image information having an aspect ratio of 16: 9 Information on a display screen with a 4: 3 aspect ratio. It is known to slow down the direction towards the vertical edge of the display screen. This deceleration A possible way to achieve is to use an S-correction capacitor in series with the line deflection coil. Too small a value. In this way, all image information is displayed on the entire display screen. , And no geometric distortion is generated at the center of the display screen. This known method of reducing the horizontal deflection speed in the direction of the vertical edge of the display screen is described in Table 1. The purpose is to reduce the decrease in the amount of light in the direction of the edge of the display screen. There is no.   In the case where the reduction of the light amount is completely or partially compensated according to the first aspect of the present invention. Means that image information having a predetermined aspect ratio has (almost) the same aspect ratio. This point is displayed on the display screen, which indicates that the image signal has an aspect ratio of 16: 9. EP for compressing a signal for display on a display screen having a 4: 3 aspect ratio -A-0, 567, 301. Deflection speed The control of the deflection speed according to the invention, which controls to reduce the reduction, Depends on changes in glass thickness and thus deflects to introduce the desired geometric distortion It is completely different from the deflection speed control by EP-A-0,567,301 which controls the speed. Results.   EP-A-0,567,301 also has an aspect ratio of 16: 9. Completely transform image information in different ways on a display screen with 4: 3 aspect ratio An example of the display is shown. In this embodiment, the vertical edge direction of the display screen The reduction of the horizontal deflection speed of the display screen is combined with the increase of the vertical deflection speed in the horizontal direction of the display screen. I match. In the present invention, when it is necessary to correct the decrease in the amount of light in the vertical direction, The vertical deflection speed in the direction of the horizontal edge of the display screen to reduce the amount of light in the vertical direction. Reduce reduction.   Controlling the deflection speed shifts the position of the image signal on the display screen. An embodiment of the method according to the present invention controls the instant of generation of an image signal. Thereby completely or partially compensate for position shifts resulting from reduced deflection speeds Have the advantage of being. The temporal shift of the generation position of the image signal is performed by clock modulation or compensation. This can be achieved by known techniques such as those in between. In clock modulation, the image signal The signal is written to the memory at a constant clock and read from the memory at a variable clock, for example. Protrude. In interpolation, the supplied image signal is processed by an interpolation algorithm and shifted. An image signal having correct information is obtained instantaneously.   An embodiment of the method according to the present invention modulates only the deflection speed in the line direction. I do. In this embodiment, the time shift of the image information is simplified by using, for example, a line memory. It has the advantage that it can be simply realized. Line obtained by horizontal deflection In conventional deflections where the vertical deflections are continuous with each other, the horizontal deflection is the horizontal deflection. It is a direction. Transposition that vertical lines obtained by vertical deflection are continuous with each other in the horizontal direction In scanning, the deflection in the line direction is vertical deflection.   An embodiment of the method according to the invention is characterized in that the display screen has various frames. Based on the possible changes in the line direction of the glass thickness at the camera position. This example Provides good compensation for light loss.   In an embodiment of the method according to the invention as defined in claim 5, the deflection is provided at the edge of the display screen. Direction is slowed down more than necessary to compensate for the decrease in light quantity. as a result The resulting increase in the amount of light in the direction of the edge of the display screen indicates the beam current To compensate completely or partially by reducing in the direction of the edges. This purpose The modulated beam current is controlled by the correction waveform to A corrected electron beam with fewer electrons per second than this beam current Get By reducing the modulated beam current in the direction of the edge of the display screen The spot size growth along the edge of the display screen (also called spot growth). Is limited). The decrease in the modulated beam current can be The amplitude of the signal is controlled by known contrast control means, or the DC This can be achieved by controlling the bell with known brightness control means.   An embodiment of the display device according to the present invention described in claim 7 is a display device according to an embodiment of the present invention. The reduction of the light amount can be corrected in many display tubes by parabolic correction of the deflection speed. It is based on the recognition that the fruits will be achieved. Such a decrease in deflection speed is relevant. The S-correction capacitor in series with the deflection coil It can be more easily realized.   According to the fourth aspect of the present invention, at least a change in the deflection speed in the line direction is displayed. Brightness uniformity by controlling to almost compensate for the decrease in light intensity in the edge direction of the screen Has been improved. To substantially compensate for this decrease in light quantity according to the present invention, EP-A- 0,567,301, the image signal having the aspect ratio of 16: 9 is converted to 4: 3. Required to be compressed for display on a display screen with an aspect ratio of A change different from the change in the deflection speed in the line direction is required.   To improve the brightness uniformity according to the fifth aspect of the present invention, the deflection speed of the electron beam is The deflection is controlled so that the degree decreases toward the edge of the display screen. deflection The position error of the image information caused by the speed control is controlled by controlling the instant at which the image signal is generated. And decrease by. As described above, the temporal shift of the generation position of the image signal is It can be obtained by known techniques such as clock modulation or interpolation. In contrast The purpose of EP-A-0,567,301 is to increase in the direction of the edge of the display screen. Is to intentionally introduce a position error.   These and other features of the invention will be apparent from the description of the embodiments which follow. become.   In the drawing,   FIG. 1 shows an embodiment of the display device of the present invention,   FIG. 2 shows some waveforms for explaining the operation of the display device of FIG.   FIG. 1 shows a display device of the present invention. The color display tube 1 has control electrodes 11, 12, 13 And a display screen 10 are provided. The display screen 10 has three primary colors of fluorescent light. A body (not shown) is provided. The control signals Vc1, extracted from the image signal Pi, The control electrodes 11, 12, and 13 are driven by Vc2 and Vc3 to control the electrons of the individual electron beams. Modulate a number. Each modulated electron beam is associated with one phosphor. These changes The tuned electron beam constitutes a modulated composite electron beam. This modulated complex The amount of radiation emitted by the display screen 10 based on the number of electrons per second in the combined electron beam Is determined. The deflection unit 5 includes a field deflection coil Lv and a line deflection coil. Lh and a deflection driving circuit 5 for driving the field and line deflection coils Lv and Lh. With zero. The deflection drive circuit 50 is extracted by the synchronization circuit 6 from the image signal Pi. The received vertical synchronization information Vs and horizontal synchronization information Hs are synchronized with the image signal Pi. Field and line deflection coils Lv and Lh The line deflection currents Iv and Ih are generated.   The waveform generation circuit 4 receives the horizontal and vertical synchronization information Hs and Vs, and generates a first correction waveform. C1 to the deflection driving circuit 50, the second correction waveform C2 to the time correction circuit 3, and the third The correction waveform C3 is supplied to the beam current correction circuit 2. The time correction circuit 3 outputs the image signal Pi And outputs a time-shifted image signal Pd. This time shift amount is the second Is determined by the correction waveform C2. The beam current correction circuit 2 calculates the time-shifted image. It receives the image signal Pd and outputs control voltages Vc1, Vc2, and Vc3. Modulated composite power The number of electrons per second in the child beam (hereinafter referred to as beam current value) is the third correction waveform Determined by C3. In this embodiment, the line deflection current Ih is added to the first correction signal C1. More control, decreasing the horizontal deflection speed towards the edge of the display screen 10 You. The field deflection current Iv decreases toward the edge of the display screen 10. A fourth correction waveform to be generated can also be generated. Display screen 10 for deflection speed When it decreases toward the edge of, the decrease in luminance is suppressed.   Incorrect position of the image signal Pi caused by controlling the deflection speed on the display screen 10. The difference can be compensated through the time correction circuit 3 by the second correction waveform C2.   The deceleration of the deflection in the edge direction of the display screen 10 is controlled by the It can be greater than required for the desired reduction in brightness reduction. The result As a result, a large increase in the amount of light causes the shape of the third correction waveform C3 to change with the beam current value (change). The number of electrons per second in the modulated composite electron beam) toward the display screen 10 Complete or partial compensation by choosing to decrease as Can be. The beam current value can be adjusted, for example, by contrast control, That is, control can be performed by multiplying the time shift image signal Pd by the third correction signal C3. Can be. This contrast control is based on the existing contrast control in the image display device. Or can be incorporated as additional features.   Further, the decrease in the deflection speed in the edge direction of the display screen is caused by the line deflection coil Lh. By arranging an S-shaped correction capacitor Cs in series, or This can be realized by selecting the value of Cs to be smaller than a normal value. In this case, the first correction signal C1 can be omitted. Commonly known circuits Then, the value of the S-shaped correction capacitor Cs is set to a high value in the edge direction of the display screen 10. Horizontal in the vertical edge direction of the display screen 10 to best compensate for too much deflection speed. The selection is made such that a reduction in the terminal voltage of the deflection coil Lh is obtained. This too high bias The heading speed results from the display screen 10 being substantially flat. In the present invention, The value of the S-shaped correction capacitor Cs is intentionally selected to be smaller than the value required for normal deflection. Then, the line deflection speed is decreased toward the edge of the display screen 10. In addition, for example, an S-shape that is too large due to a waveform generator disposed in the deflection control circuit 50 Field deflection speed by generating a field control signal with a correction amount May be reduced towards the edge of the display screen. EP-A-0,56 7, 301, the deflection speed is displayed so as to introduce a predetermined geometric distortion. It is known to decelerate toward the edge of the motor, so the degree of correction differs from that of the present invention. It is determined based on certain criteria.   FIG. 2 shows some waveforms for explaining the operation of the display device of FIG. Period t0-t 1 is one horizontal time interval in which one line is written on the display screen 10. Corresponding. The dashed line in FIG. 2a shows the display screen 10 at (almost) constant horizontal deflection speed. 1 shows a conventional horizontal deflection current Iho provided with the required amount of S-curve correction to scan. Deliberately selecting S-correction capacitor Cs to an excessively small value in accordance with the present invention The corrected horizontal deflection current Ihc having an S-shape correction that is too large is shown by the solid line. FIG. 2b shows the horizontal deflection speed vh, the dashed line is the constant associated with the conventional horizontal deflection current Iho. Shows the horizontal deflection speed vho of. The solid line indicates the corrected horizontal deflection speed vch1 according to the present invention. Increases slightly at the center of the display screen 10 and toward the edge of the display screen 10 It shows that it decreases as it goes. FIG. 2c shows a line indicated by a constant beam current Is shown. The dashed curve lo indicates the display size for the conventional constant horizontal deflection speed vho. Toward the edge of the display screen 10 at a predetermined frame position of the clean 10 This indicates that the light amount decreases. Solid line lc1 is for corrected horizontal deflection speed vh1 Indicates that a constant amount of radiation is generated. As shown by the solid curve vhc2 in FIG. It is also possible to reduce the deflection speed more than is necessary to compensate for Wear. In this case, as shown by the solid curve lc2 in FIG. The amount of light that increases toward the edge of is obtained. This increase in light intensity indicates the beam current This can be compensated for by decreasing towards the edge of the screen 10. Ma It is also possible to reduce the deflection speed to less than that required to compensate for Of course you can. The waveform shown in FIG. 2 is merely an example, Simple waveforms composed of minute combinations are also preferable for suppressing spot growth.   The above-described embodiments illustrate the present invention and limit the present invention. Instead, one skilled in the art should not depart from the scope of the present invention as set forth in the claims. Many modifications and variations are possible. Reference signs in parentheses in the claims indicate claims. It does not limit the enclosure. In particular, the waveform generation circuit 4, the time correction circuit 3, and the beam The current correction circuit 2 can be implemented in hardware or an integrated circuit including various elements. And / or can be implemented by a suitable program control processor, Both are within the scope of the present invention. The present invention controls the amount of light in the horizontal and / or vertical It can be used to keep as constant as possible. Low brightness according to the present invention The reduction is also suitable for a display tube using one electron beam.

Claims (1)

[Claims] 1. The brightness on the display screen (10) of the display tube (1) provided with the control electrodes (11, 12, 13) A method for improving uniformity, in which control electrodes (11, 12, 13) are responsive to an image signal (Pi). Driving (2) to generate a modulated electron beam; and Deflecting the beam to display the image signal (Pi) on the display screen (10) (5) ), And the image signal (Pi) corresponds to the aspect ratio of the display screen. In a method for improving luminance uniformity having a ratio, the method further comprises:     The deflection (5) is controlled by adjusting the deflection speed of the modulated electron beam on the display screen (10). Including a step (C1; Cs) of controlling to decrease from the center to the edge. Characteristic brightness uniformity improvement method. 2. The method further comprises the step of determining the instant of the occurrence of the image signal on the display screen (10). Comprising a step (3) of controlling the position error of the image signal (Pi) to be reduced. 2. The method for improving brightness uniformity according to claim 1, wherein: 3. Perform the deflection (5) in the line and field directions, and control the deflection (C1; C s), the deflection speed in the line direction is reduced from the center of the display screen (10) to the edge 2. The method for improving brightness uniformity according to claim 1, wherein: 4. The decrease in the deflection speed in the line direction is the position in the field direction on the display screen (10). 4. The method for improving brightness uniformity according to claim 3, wherein the method depends on the position. 5. The decrease in the deflection speed from the center of the display screen (10) to the edge direction Overcompensating the reduction of the light output of (10) towards the edge of the display screen (10) and the method Further controls the modulated electron beam from the center to the edge of the display screen (10). A corrected electron beam with fewer electrons per second 2. The method according to claim 1, further comprising the step of generating a correction waveform to be obtained. The method of improving the brightness uniformity described above. 6. The image is displayed on the display screen (10) of the display tube (1) provided with the control electrodes (11, 12, 13). A display device for displaying a signal (Pi),     Drives the control electrodes (11, 12, 13) in response to the image signal (Pi) and modulates them in the display tube (1) Driving means (2) for generating a focused electron beam,     The image signal (Pi) is displayed on the display screen (10) by deflecting the modulated electron beam. In the display device comprising a deflecting means (5) to be shown, the display device further comprises:     The deflection speed of the electron beam is adjusted so that improved brightness uniformity is obtained. A correction means (C1; Cs) for decreasing from the center of the display screen (10) toward the edge. A display device. 7. The deflection unit (5) includes a line deflection coil (Lh), and the correction unit (C1; Cs) includes a line deflection coil (Lh). Including an S-shaped correction capacitor (Cs) arranged in series with the in-deflection coil (Lh), The correction capacitor (Cs) has a value less than the nominal value associated with an almost constant deflection speed , The deflection speed of the electron beam decreases from the center to the edge of the display screen (10) The display device according to claim 6, wherein the display device is configured as described above. 8. A correction circuit for improving the brightness uniformity on the display screen (10) of the display tube (1). In response to the image signal (Pi), the control electrodes (11, 12, 13) of the display tube (1) are driven and modulated. A correction circuit including a driving means (2) for generating a focused electron beam in the display tube (1). The correction circuit further includes:     The display speed is adjusted so that the deflection speed of the electron beam is improved for improved brightness uniformity. Characterized in that it comprises means (4) for reducing from the center of the clean (10) toward the edge. Correction circuit. 9. The brightness on the display screen (10) of the display tube (1) provided with the control electrodes (11, 12, 13) A method for improving uniformity, in which control electrodes (11, 12, 13) are responded to an image signal (Pi). Driving (2) to generate a modulated electron beam; and The beam is deflected in the line and field directions to display the image signal (Pi) on the display screen (1 0) The method for improving brightness uniformity comprising the step (5) of displaying on the Is also     Deflection (5), the deflection speed of the modulated electron beam at least in the line direction Decreases from the center of the display screen (10) toward the edge, and at least one frame Controlling such that the decrease in the optical output in the line direction at the position is substantially compensated. (C1; Cs). 10. Brightness on the display screen (10) of the display tube (1) provided with the control electrodes (11, 12, 13) A method for improving the degree of uniformity, the control electrodes (11, 12, 13) in response to the image signal (Pi) Driving the laser beam to generate a modulated electron beam (2); and Deflecting the secondary beam to display the image signal (Pi) on the display screen (10) (5) In the brightness uniformity improvement method comprising, the method further comprises:     Deflection (5), the deflection speed of the modulated electron beam at least in the line direction (C1) to decrease from the center of the display screen toward the edge. Cs),     The instant of the generation of the image signal (Pi) is displayed to reduce the position error on the display screen (10). (3) controlling the brightness uniformity.