1. Field of the Invention
The present invention relates to a plasma display device.
2. Description of the Related Art
At present, a plasma display device having an AC discharge type plasma display panel (hereinafter referred to as PDP), as a thin display device, is known.
The PDP has a plurality of column electrodes and a plurality of row electrode pairs arranged to intersect with the column electrodes via a discharge space. A discharge gas is sealed within the discharge space. At the intersections of the row electrode pairs and the column electrodes, discharge cells, each including the discharge space, are formed which respectively emit red light, green light, and blue light when discharging.
Each of the discharge cells uses discharge phenomenon to emit light, therefore it provides only two states, i.e., a “lighting state” to emit light at a predetermined brightness and an “extinction state”. In other words, the discharge cell only expresses two gray scale levels of brightness. Thus, in order to display halftone brightness corresponding to input video signals in the discharge cells described above, gray scale driving using a subfield method is applied (for example, see Japanese Patent Kokai No. 2000-338932).
In the subfield method, a display period for one field is divided into N subfields, and each of the subfields is designed to have a period for continuously performing either light emission or black out in the discharge cell. With this arrangement, each of the discharge cells is controlled to either a light emission state or a black out state during the period assigned to each subfield in accordance with the input video signal. Consequently, various levels of halftone brightness can be displayed at 2N (N denotes the number of subfields) levels (hereinafter referred to as gray scale levels) by the combination of subfields performing light emission within one field display period.
In performing the gray scale driving based on the subfield method, a drive unit (not shown) applies various drive pulses to the PDP to cause various discharges in the discharge cells. For example, in the first subfield, the drive unit firstly applies a reset pulse to the row electrode pairs of the PDP to create a reset discharge in all the discharge cells. On this occasion, the reset discharge uniformly forms a predetermined amount of wall charge in all the discharge cells. Subsequently, the drive unit selectively creates an erase discharge in the discharge cells from one horizontal scanning line (hereinafter referred to as a display line) to another in accordance with the input video signal. On this occasion, in the discharge cell where selective erase discharge occurs, the wall charge remaining in this discharge cell disappears. On the other hand, in the discharge cell where no selective erase discharge occurs, the wall charge formed by the reset discharge remains as it is. Subsequently, the drive unit alternately and simultaneously applies sustain pulses between all the row electrode pairs by the number of sustain pulses corresponding to the first subfield. In response to such application of the sustain pulse, only the discharge cell with the remaining wall charge repeatedly performs sustain discharge only during a period corresponding to the first subfield, and maintains the light emission state due to this sustain discharge.
However, in the PDP, the amount of wall charge formed by various discharges as described above varies due to temperature variation in the panel, the variation in display brightness, aging, etc. Therefore, there is a problem that discharge intensity fluctuates, thereby deteriorating the display quality.
The invention has been made to solve the problem. An object of the present invention is to provide a plasma display device which can stabilize discharge and improve the display quality.
A plasma display device according to a first aspect of the invention includes a plasma display panel having a plurality of row electrode pairs and a plurality of column electrodes arranged to intersect with the row electrode pairs to form a display cell at each intersection thereof. The plasma display device displays an image by configuring a plurality of subfields within a unit display period of an input video signal, and each of the subfields includes an address period and a sustain period. The plasma display device includes a magnesium oxide layer formed in each of the display cells. The plasma display device also includes addressing means for selectively generating address discharge in each of the display cells in accordance with pixel data based on the video signal in the address period, and sustaining means for repeatedly applying sustain pulses between row electrodes configuring the row electrode pairs in the sustain period. A rear edge part of the sustain pulse applied at the end of the sustain period of each of the subfields is formed by a first section in which a voltage value slowly changes from a peak voltage value of the sustain pulse to a predetermined first voltage value, a second section in which the first voltage value is maintained for a predetermined period, and a third section in which the voltage value slowly changes from the first voltage value to a second voltage value having a polarity different from that of the first voltage value.
In a plasma display device according to an embodiment of the invention, a rear edge part of the sustain pulse which is applied to the end of a sustain period of each of the subfields is formed by a first section in which a voltage value slowly changes from a peak voltage value of the sustain pulse to a first voltage value, a second section in which the first voltage value is maintained for a predetermined period, and a third section in which the voltage value slowly changes from the first voltage value to a second voltage value having a polarity different from that of the first voltage value. With this arrangement, spurious discharge at the rear edge part of the sustain pulse can be prevented, and proper setting of the predetermined period and the second voltage value can control the amount of remaining wall charge so as to preferably generate selective discharge in an address period right after the setting.
As shown in
The PDP 50 is formed with column electrodes D1 to Dm which are arranged to extend in the longitudinal direction (vertical direction) of a two-dimensional display screen, and row electrodes X1 to Xn and row electrodes Y1 to Yn which are arranged to extend in the transverse direction (horizontal direction). On this occasion, row electrode pairs (Y1, X1), (Y2, X2), (Y3, X3), to (Yn, Xn) serve as the first display line to the nth display line of the PDP 50, and each of the row electrode pairs is formed by two electrodes adjacent to each other. At intersections of the display lines and the column electrodes D1 to Dm, i.e., areas surrounded by alternate long and short dashed lines in
As shown in
On a rear substrate 14 which is arranged in parallel with the front transparent substrate 10, the column electrodes D are formed to extend in a direction orthogonal to the row electrode pairs (X, Y) and arranged at positions respectively facing to the transparent electrodes Xa and Ya of the row electrode pairs (X, Y). On the rear substrate 14, a white column electrode protection layer 15 is further formed to cover the column electrode D. On the column electrode protection layer 15, ribs 16 are formed. The rib 16 is formed to have a ladder shape such that a lateral wall 16A extending in the transverse direction of the two-dimensional display screen is arranged at the position corresponding to the bus electrodes Xb and Yb of the row electrode pairs (X, Y), and that a vertical wall 16B extending in the longitudinal direction of the two-dimensional display screen is arranged at the middle position between the adjacent column electrodes D. It should be noted that the rib 16 of a ladder shape is formed at each of the display lines of the PDP 50 as shown in
The drive control circuit 56 controls the X electrode driver 51, the Y electrode driver 53, and the address driver 55 in order to gray scale drive each of the display cells PC of the PDP 50 as shown in
The X electrode driver 51, the Y electrode driver 53, and the address driver 55 generate various drive pulses to perform the driving operation shown in
In the reset period R, the X electrode driver 51 simultaneously applies reset pulses RPX of negative polarity as shown in
It should be noted that, in the reset period R, in order to improve the contrast, the first reset pulses RPY1 each having a slow voltage change at the rise time are applied to the row electrodes Y to generate weak first reset discharges between the transparent electrodes Ya and Xa, which are T-shapes.
Next, in the address period W, the address driver 55 generates a pixel data pulse based on an input video signal for setting whether the display cell PC emits light or not in the subfield. For example, the address driver 55 generates a pixel data pulse of high voltage at the display cell PC when the display cell PC is made to emit light, whereas it generates a pixel data pulse of low voltage at the display cell PC when the display cell PC is made not to emit light. Then, the address driver 55 sequentially applies the pixel data pulses to the column electrodes D1 to Dm as pixel data pulse groups DP1, DP2, to DPn for every display line (m pulses). During this period, the Y electrode driver 53 sequentially applies scanning pulses SP of negative polarity to the row electrodes Y1 to Yn in synchronization with the timing of the pixel data pulse groups DP1 to DPn. On this occasion, discharge (selective discharge) is generated only in the display cell PC to which both the scanning pulse SP and the pixel data pulse of high voltage are applied. Consequently, a predetermined amount of wall charge is formed on the surfaces of the magnesium oxide layer 13 and the fluorescent layer 17 in the discharge space S of such display cell PC. It should be noted that, since the selective discharge as described above is not generated in the display cell PC to which the pixel data pulse of low voltage is applied even though the scanning pulse SP is applied. This maintains the state of the wall charge formed in the display cell PC until just before.
Specifically, operation of the address period W establishes either the lighting mode state with a predetermined amount of wall charge or the extinction mode state without a predetermined amount of wall charge in the display cell PC based on the input video signal.
Next, in the sustain period I, the X electrode driver 51 and the Y electrode driver 53 alternately and repeatedly apply the sustain pulses IPX and IPY of positive polarity to the row electrodes X1 to Xn and Y1 to Yn. It should be noted that the sustain pulse IP to be applied at the end of the sustain period I in each of the subfields (for example, a sustain pulse IPYE in
The magnesium oxide layer 13 formed in each of the display cells PC contains a vapor-phase-oxidized magnesium monocrystal of a relatively larger shape as shown in
Therefore, since the vapor-phase-oxidized magnesium monocrystal has an energy level corresponding to 235 nm as described above, it can be assumed that the monocrystal captures electrons for a long time (a few milliseconds) and releases these electrons due to application of an electric field at the time of selective discharge so as to quickly obtain initial electrons necessary for the discharge. Therefore, when the magnesium oxide layer 13 as shown in
As described above, when the magnesium oxide layer 13 containing the vapor-phase-oxidized magnesium monocrystal as shown in
As a countermeasure, in repeatedly applying the sustain pulses IP in each of the sustain periods I, the Y electrode driver 53 applies the sustain pulse IPYE with the rear edge part REG as shown in
In the X electrode driver 51, a direct current power supply B2 generates DC voltage −Vr of negative polarity, and applies it to a switching device S8. The switching device S8 is turned to the ON state in accordance with a switching signal supplied from the drive control circuit 56, and applies voltage −Vr supplied from the direct current power supply B2 to the row electrode X through a resister R1. A direct current power supply B1 generates DC voltage Vs of positive polarity, and applies it to a switching device S3. The switching device S3 is turned to the ON state in accordance with a switching signal supplied from the drive control circuit 56, and applies the voltage Vs supplied from the direct current power supply B1 to the row electrode X. A switching device S1 is turned to the ON state in accordance with a switching signal supplied from the drive control circuit 56, and applies the voltage at one of the electrode terminals of a condenser C1 to the row electrode X through a coil L1 and a diode D1. A switching device S2 is turned to the ON state in accordance with a switching signal supplied from the drive control circuit 56, and applies the voltage on the row electrodes X to one of the electrode terminals of the condenser C1 through a coil L2 and a diode D2. A switching device S4 is turned to the ON state in accordance with a switching signal supplied from the drive control circuit 56, and grounds the row electrodes X.
On the other hand, in the Y electrode driver 53, a direct current power supply B3 generates DC voltage Vs of positive polarity, and applies it to a switching device S13. The switching device S13 is turned to the ON state in accordance with a switching signal supplied from the drive control circuit 56, and applies the voltage Vs supplied from the direct current power supply B3 to a line 12. A switching device S11 is turned to the ON state in accordance with a switching signal supplied from the drive control circuit 56, and applies the voltage at one of the electrode terminals of a condenser C2 to the line 12 through a coil L3 and a diode D3. A switching device S2 is turned to the ON state in accordance with a switching signal supplied from the drive control circuit 56, and applies the voltage on the line 12 to one of the electrode terminals of the condenser C2 through a coil L4 and a diode D4. A switching device S1 is turned to the ON state in accordance with a switching signal supplied from the drive control circuit 56, and grounds the line 12. A switching device 15 is turned to the ON state in accordance with a switching signal supplied from the drive control circuit 56, and connects the line 12 to a line 13. A direct current power supply B4 generates DC voltage VR of positive polarity, and applies it to a switching device S16. The switching device S16 is turned to the ON state in accordance with a switching signal supplied from the drive control circuit 56, and applies the voltage VR supplied from the direct current power supply B4 to the line 13 through a resister R2. A direct current power supply B5 generates DC voltage −Voff of negative polarity, and applies it to a switching device S17. The switching device S17 is turned to the ON state in accordance with a switching signal supplied from the drive control circuit 56, and applies the voltage −Voff of negative polarity supplied from the direct current power supply B5 to the line 13. A direct current power supply B6 generates DC voltage Vh. The negative electrode terminal of the direct current power supply B6 is connected to the anode electrode of the line 13, a switching device S22 and the diode D6 respectively, and the positive electrode terminal thereof is connected to the cathode electrodes of a switching device S21 and a diode D5 respectively. The switching device S21 is turned to the ON state in accordance with a switching signal supplied from the drive control circuit 56, short-circuits between the anode electrode and the cathode electrode of the diode D5, and applies the voltage at the positive electrode terminal of the direct current power supply B6 to the row electrodes Y. The switching device S22 is turned to the ON state in accordance with a switching signal supplied from the drive control circuit 56, short-circuits between the anode electrode and the cathode electrode of the diode D6, and applies the voltage at the negative electrode terminal of the direct current power supply B6 to the row electrodes Y.
Hereinafter, the operation of generating various drive pulses by the configuration shown in
First, in the reset period R, the drive control circuit 56 sets the switching device S8 of the X electrode driver 51 to the ON state, and the switching device S16 of the Y electrode driver 53 to the ON state for a predetermined period. Thus, as shown in
Subsequently, in the address period W, the drive control circuit 56 sets one of the switching devices S21 and S22 of the Y electrode driver 53 to the ON state, and the other to the OFF state. On this occasion, during the ON state of the switching device S22, the scanning pulses SP of negative polarity as shown in
In the sustain period I, the drive control circuit 56 fixes the switching devices S16 and S22 of the Y electrode driver 53 to the OFF state, and the switching devices S15 and S21 of the Y electrode driver 53 to the ON state. During this period, the drive control circuit 56 repeatedly implements the switching sequence such that the switching devices S1 to S3 of the X electrode driver 51 are alternately and sequentially set to the ON state in the order of S1, S3 and S2. Thus, the sustain pulses IPX of positive polarity as shown in
However, only when the sustain pulse IPYE, to be applied at the end, is generated, the drive control circuit 56 performs drive control over the Y electrode driver 53 based on the switching sequence shown in
In
The drive control circuit 56 maintains the ON state of the switching device S12 for a predetermined period Tb1, and then switches it to the OFF state. It further switches the switching device S17 to the ON state after a predetermined period Tb2 has elapsed. Consequently, since all the switching devices S11 to S14 and S17 are in the OFF state for a predetermined period Tb2, the row electrode Y is turned to the high impedance state. Therefore, the voltage on the row electrode Y is maintained for this predetermined period Tb2 at voltage V1 which is the voltage right before the switching device S12 is switched from the ON state to the OFF state. On this occasion, since the voltage drop is temporarily suspended, spurious discharge which occurs at the voltage drop can be suppressed.
Then, after this predetermined period Tb2 has elapsed, the drive control circuit 56 sets the switching device S17 to the ON state for a predetermined period Tb3. Then, since the voltage −Voff at the negative electrode terminal of the direct current power supply B5 is applied to the row electrode Y through the switching device S22, the voltage on the row electrodes Y slowly drops, and reaches negative voltage −V2 (for example, voltage −Voff). After that, the drive control circuit 56 sets the switching device S14 to the ON state. Consequently, the voltage on the row electrodes Y reaches the ground potential, that is, 0 volt, from the negative voltage −V2. On this occasion, as shown in
As described above, the section (Tb2) is provided in the rear edge part REG of the sustain pulse IPYE such that the voltage value is maintained at a predetermined voltage V1 for a predetermined period after the voltage is slowly changed from a peak voltage value to the voltage V1, thereby preventing spurious discharge at the rear edge part of the sustain pulse. Furthermore, the section (Tb3) is provided in the rear edge part REG such that the voltage is slowly changed from the voltage V1 to the predetermined voltage −V2 having polarity different from that of the voltage V1. On this occasion, the predetermined period Tb2 and the voltage −V2 are properly set, thereby allowing control of the amount of remaining wall charge to the amount that can preferably generate selective discharge in the address period W right after that period. Thus, by the sustain pulse IPYE described above, the margin for selective discharge in the address period implemented right after the period can be increased.
As described above, according to the plasma display device of the invention, it becomes possible to stabilize the discharge and to improve the display quality.
This application is based on a Japanese Patent Application No. 2005-171470 which is herein incorporated by reference.
Number | Date | Country | Kind |
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2005-171470 | Jun 2005 | JP | national |