1. Field of the Invention
The present invention relates to a method for driving plasma display panels.
2. Description of the Related Art
In a surface discharge AC type panel that typifies plasma display panels (hereinafter abbreviated as “panel”), a number of discharge cells are formed between an oppositely disposed front panel and a rear panel. On the front panel, two or more pairs of display electrodes comprising a scan electrode and a sustain electrode are formed in parallel on a front glass substrate. Further, on the front panel, a dielectric layer and a protective layer are formed in a manner covering the display electrodes. On the rear panel, two or more parallel data electrodes are formed on a rear glass substrate and a dielectric layer is formed covering the data electrodes. In addition, two or more barrier ribs are formed on top of the dielectric layer in parallel to the data electrodes. In addition, a phosphor layer is formed on the surface of the dielectric layer and the sides of the barrier ribs.
The front panel and the rear panel are oppositely disposed and sealed in a manner such that the display electrodes and the data electrodes make a two-level crossing, and a discharge gas is filled in the inner discharge space. Discharge cells are formed on the sections where the display electrodes and the date electrodes face each other in this way. In a panel having such a structure, ultraviolet ray is generated by gas discharge in each of the discharge cells. Color display is enabled by excitation emission of each of Red (R), Green (G) and Blue (B) phosphors with the ultraviolet ray.
As a method for driving a panel, the sub-field method is generally employed. In this method, the period of one field is divided into plural sub-fields and half-tone expression is performed by the combination of the sub-fields to be fired. Among sub-field methods, a drive method in which contrast ratio is improved by reducing the emission of light which is not related to half tone expression is reduced as much as possible is disclosed in Japanese Patent Unexamined Publication No. 2002-351396.
A brief description of the sub-field method is given below. Each of the sub-fields has an initialization period, a writing period and a sustain period. First, in the initialization period, initialization discharge simultaneously takes place in all discharge cells and erases hysteresis of earlier wall charges existing in the individual discharge cells, and wall charges necessary for subsequent writing action are formed. In addition, a priming (a detonator for discharge or an excitation particle) for decreasing a delay in discharge and stably generating writing discharge is generated.
During the subsequent writing period, scanning pulses are sequentially applied to the scan electrodes while applying to the data electrodes writing pulses corresponding to the image signal to be displayed. Selective writing discharge is thus generated between the scan electrodes and data electrodes thereby selectively forming wall charges. During the sustain period, a predetermined number of sustain pulses corresponding to brightness weight are alternately applied to the scan electrodes and sustain electrodes to selectively discharge the discharge cells in which wall charges have been formed by writing discharge thus causing light emission.
In such a panel of conventional method, dispersion of discharge timing occurs from discharge cell to discharge cell depending on the status of display. As a result, the emission intensity may vary from discharge cell to discharge cell and a screen having a region of brightness non-uniformity may be produced.
It is an object of the present invention to prevent deterioration of display quality due to non-uniformity of brightness without increasing power consumption.
In the method for driving a plasma display panel of the present invention, discharge cells are formed at the intersections where the scan electrodes and sustain electrodes meet with the data electrodes. The method has an initialization period, a writing period and a sustain period. The initialization period is a period in which initialization discharge is generated in the discharge cells. The writing period is a period in which writing discharge is generated in the discharge cells. The sustain period is a period in which sustain discharge is generated by alternately applying sustain pulses to the scan electrode and sustain electrode of a discharge cell. The rise time of the sustain pulses to be applied to the scan electrode and sustain electrode during the sustain period is shortened at a frequency of once every several times.
Also, in the present invention, the rise time of the sustain pulses to be applied to the scan electrode and sustain electrode during the sustain period is shortened at a frequency of once every three times or once every two times.
According to the above-described method, it is possible to reduce generation of non-uniform brightness regions on a screen without changing the voltage and pulse width of the sustain pulses thus suppressing an increase in the power consumption.
A description of the method for driving a plasma display panel of the present invention is given with reference to drawings.
A plurality of data electrodes 9 covered with insulating layer 8 are provided on rear substrate 3 and barrier ribs 10 are provided in parallel to the data electrodes 9 the on insulating layer 8 between adjacent data electrodes 9. Phosphor 11 is provided on the surface of insulating layer 8 and on the sides of barrier ribs 10. Front substrate 2 and rear substrate 3 are oppositely disposed in the direction in which scan electrode 4 and sustain electrode 5 cross data electrode 9. A mixture of neon and xenon, for example, is filled as a discharge gas in the discharge space formed between the two substrates.
In
Scanning line conversion section 19 converts the picture data into picture data that correspond to the number of pixels of panel 1 and supplies the data to sub-field conversion section 20. Sub-field conversion section 20 divides the picture data of each pixel into plural bits corresponding to plural sub-fields and outputs picture data of each sub-field to data electrode drive circuit 12. Data electrode drive circuit 12 converts picture data of each sub-field into a signal corresponding to each of the data electrodes D1 to Dm and drives each data electrode.
Timing generator circuit 15 generates timing signals based on horizontal synchronizing signal H and vertical synchronizing signal V and supplies the timing signals to scan electrode drive circuit 13 and sustain electrode drive circuit 14. Scan electrode drive circuit 13 supplies driving voltage to scan electrodes SCN1 to SCNn based on the timing signal. Sustain electrode drive circuit 14 supplies driving voltage to sustain electrodes SUS1 to SUSn based on the timing signal.
Next, a description of the driving voltage for driving the panel and its action is given.
First, a description is given on the driving voltage waveform of the all-cell initialization sub-field and its action. In
Subsequently, a gradually decreasing ramp voltage that decreases from a voltage Vg (V) toward a voltage Va (V) is applied to scan electrodes SCN1 to SCNn while maintaining sustain electrodes SUS1 to SUSn at a positive voltage Vh (V). As a result, the second weak initialization discharge takes place in all the discharge cells, the wall voltages on scan electrodes SCN1 to SCNn and the wall voltages on sustain electrodes SUS1 to SUSn are weakened, and the wall voltages on data electrodes D1 to Dm are also adjusted to a value adequate for writing action. In short, the initialization action in the all-cell initialization sub-field is an all-cell initialization action to cause initialization discharge in all the cells.
In the subsequent writing period, scan electrodes SCN1 to SCNn are once maintained at voltage Vs (V) as shown in
Subsequently, writing discharge takes place between data electrode Dk and scan electrode SCN1 and between sustain electrode SUS1 and scan electrode SCN1, a positive wall voltage is stored on scan electrode SCN1 of this discharge cell, a negative wall voltage is stored on sustain electrode SUS1, and a negative wall voltage is also stored on data electrode Dk. In this way, writing action of storing wall voltage on each electrode is performed by generating writing discharge in the discharge cells to be displayed on the first line. On the other hand, as the voltage at the intersection of the data electrode to which no positive writing pulse voltage Vw (V) is applied and scan electrode SCN1 does not exceed the firing voltage, no writing discharge takes place. The writing period ends after sequentially performing the above writing action until the discharge cells on the n-th line are reached.
In the subsequent sustain period, as shown in
Subsequently, sustain discharge takes place between scan electrode SCNi and sustain electrode SUSi, and a negative wall voltage is stored on scan electrode SCNi while a positive wall voltage is stored on sustain electrode SUSi. During this process, a positive wall voltage is also stored on data electrode Dk. In the discharge cells in which no writing discharge took place during the writing period, no sustain discharge takes place and the state of the wall voltage at the end of the initialization period is maintained. Subsequently, scan electrodes SUS1 to SUSn are returned to 0 (V) and a positive sustain pulse voltage Vm (V) is applied to sustain electrodes SUS1 to SUSn.
Then, in the discharge cells in which sustain discharge took place, as the voltage across sustain electrode SUSi and scan electrode SCNi exceeds the firing voltage, sustain discharge takes place again between sustain electrode SUSi and scan electrode SCNi and a negative wall voltage is stored on sustain electrode SUSi while a positive wall voltage is stored on scan electrode SCNi. Likewise, by subsequently alternately applying sustain pulses to scan electrodes SCN1 to SCNn and sustain electrodes SUS1 to SUSn, sustain discharge continues to take place in the discharge cells in which writing discharge took place during the writing period.
In the meantime, the wall voltages on scan electrodes SCN1 to SCNn and sustain electrodes SUS1 to SUSn are removed by applying, at the end of the sustain period, so-called narrow width pulses across scan electrodes SCN1 to SCNn and sustain electrodes SUS1 to SUSn while leaving the positive wall charges on data electrode Dk. In this way, sustain action during the sustain period ends.
Next, a description of the drive voltage waveform and its action during the selective initialization sub-field is given. During the selective initialization period, sustain electrodes SUS1 to SUSn are maintained at Vh (V), data electrodes D1 to Dm are maintained at 0 (V), and a ramp voltage that gradually decreases from Vq (V) toward Va (V) is applied to scan electrodes SCN1 to SCNn. Then, weak initialization discharge takes place in the discharge cells in which sustain discharge took place during the sustain period of the preceding sub-field thus weakening the wall voltages on scan electrode SCNi and sustain electrode SUSi and the wall voltage on data electrode Dk is adjusted to a value adequate for writing action.
On the other hand, no discharge takes place in the discharge cells in which no writing discharge or sustain discharge took place in the preceding sub-field, and the state of wall charges at the end of the initialization period in the preceding sub-field is maintained as is. In short, the initialization action in the selective initialization sub-field is an action of selective initialization by generating initialization discharge in the discharge cells in which sustain discharge took place in the preceding sub-field.
In the subsequent writing period and sustain period, by performing action similar to the action during the above-described writing period and sustain period of the all-cell initialization sub-field, light emission corresponding to an input video signal is enabled.
By the way, in a plasma display panel, there occurs dispersion from discharge cell to discharge cell in the timing at which discharge takes place depending on the state of display. As a result, there appears a region on the screen where brightness is non-uniform. This phenomenon of brightness non-uniformity is promoted by the voltage applied to the scan electrodes and sustain electrodes during the above-mentioned sustain period and by the distortion of waveform due to discharge current during sustain discharge.
Also, as part of an effort for increasing brightness of panels, the partial pressure of xenon used as the discharge gas is recently increased. When brightness is enhanced in this way, the above-mentioned brightness non-uniformity becomes all the more prominent.
Accordingly, in the present invention, rise time of sustain pulses to be applied to scan electrodes and sustain electrodes during the sustain period is shortened at a frequency of once every several times so as to suppress dispersion of timing at which discharge takes place in each discharge cell at the time of sustain discharge.
Also, the example shown in
As shown in
In addition, by shortening the rise time of the sustain pulses to be applied to the scan electrodes and sustain electrodes during the sustain period at a frequency of once every three times or once every two times, the dispersion of timing at which discharge takes place in each discharge cell at the time of sustain discharge may be further suppressed. Shortening of the rise time of the sustain pulses is realized by controlling the timing of action of an energy recovery circuit installed in the scan electrode drive circuit and the sustain electrode drive circuit. To put it concretely, while the energy recovery circuit first supplies electric power to the panel at the time of rising of the sustain pulses through an inductor and subsequently supplies electric power through a low-impedance power supply, it is possible to make the rising of sustain pulses steep by advancing the timing of supplying electric power from a low-impedance power supply. Shortening of the rise time may also be easily realized by changing inductance of the energy recovery circuit.
As is described above, the method for driving a plasma display panel of the present invention prevents deterioration of display quality due to brightness non-uniformity without increasing power consumption and is useful for picture display devices that use a plasma display panel.
Number | Date | Country | Kind |
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2004-152802 | May 2004 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2005/009834 | 5/24/2005 | WO | 00 | 12/7/2005 |
Publishing Document | Publishing Date | Country | Kind |
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WO2005/114626 | 12/1/2005 | WO | A |
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