JP2004086076A - Display device, driving circuit therefor, and driving method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display device, a driving circuit therefor, and a driving method which reduce the occurrence of unevenness of display at start-up and effectively perform initialization processing of a display panel. <P>SOLUTION: When a main switch of a power source part 1 is turned off in order to terminal picture display, a control part 2 detects switching from an operating state to a non-operating state of a device 10 by a turning-off signal input from the power source part 1 and stops driving control for display and inputs an operation signal for operation start to an equalizing part 4. The uniforming part 4 receives power supply from a backup power source 3 and applies an equalizing voltage V<SB>equ</SB>to one electrode of the display panel 6 to make all pixel areas discharge all at once and thus performs equalization processing. A charged state of all pixel areas is leveled by the power. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a display device and a driving circuit thereof, and a driving method thereof, in which a display operation immediately before stoppage affects image display at the time of restart, and particularly to a plasma display device, a driving circuit thereof, and a driving method.
[0002]
[Prior art]
2. Description of the Related Art In recent years, broadcasting media has been becoming higher definition and digitalized, and next generation flat panel displays suitable for this have been developed. There are several types of display methods including liquid crystal display. Among them, a plasma display panel (PDP: Plasma Display Panel) for performing light emission display using plasma discharge has been widely used in television receivers and computer displays. A cathode-ray tube (CRT: Cathode-Ray Tube), which can be made thin and has a large screen, which is considered difficult to realize, is expected to be developed particularly for large displays.
[0003]
As shown in FIG. 13, the display panel of the PDP has a structure in which two glass substrates 101 and 102 are opposed to each other via a discharge space partitioned by partition walls. Of these, sustain electrodes 107 (107X, 107Y) are arranged in pairs on the opposite surface side of front glass substrate 101 located on the display surface side, and on the rear glass substrate side in a direction intersecting with sustain electrodes 107. Address electrodes 103 are arranged. A discharge region where the sustain electrode 107 and the address electrode 103 intersect corresponds to each pixel, and a partition wall 105 is provided in a discharge space to define the pixels. Further, the phosphor 106 is applied and formed on the discharge region of each pixel, and the discharge space is filled with a discharge gas. In principle, plasma discharge occurs in the discharge gas between the electrodes where the potential difference exceeds the discharge starting voltage, and the PDP uses this to perform light-emitting display and light-emitting pixel selection. I have. Light emission for display is performed between the pair of sustain electrodes. That is, when a voltage is applied to the sustain electrode pair, a plasma discharge is generated in the gas to emit ultraviolet rays, which emit light when they hit the phosphor.
[0004]
The selection of a display pixel is performed by accumulating or erasing wall charges of the selected pixel by discharging between the sustain electrode and the address electrode in the selected pixel. FIG. 14 is a schematic configuration diagram showing an electrode structure of a PDP provided with pixels of m × n dots. Each pair of sustain electrodes 107X and 107Y has n electrodes (X ₁ , Y ₁ , X ₂ , Y ₂ , ..., X _n , Y _n ), M address electrodes 103A (A ₁ , A ₂ , ..., A _m The area corresponding to the intersection of the matrix formed by the pair of the sustain electrodes 107X and 107Y and the address electrode 103A (the area surrounded by the dotted line in the figure) corresponds to the pixel. Therefore, the address of each pixel can be represented by a matrix of the sustain electrode 107Y and the address electrode 103A, and (1, 1)... (Y _n , A _m ). Therefore, in order to selectively discharge a predetermined pixel region, it is only necessary that the voltage between both electrodes reaches the discharge start voltage and discharge occurs only after the voltage is applied to both the sustain electrode 107Y and the address electrode 103A. At this time, the value of the voltage applied to both the sustain electrode 107Y and the address electrode 103A is set in a combination that exceeds the discharge start voltage at the time of superposition.
[0005]
Light emission control for each pixel is normally performed in three stages, and each operation period is called a reset period, an address period, and a sustain (discharge sustaining) period after the operation content. Taking a selective erasing method as an example, a pulse voltage as shown in FIG. 15 is applied to three electrodes constituting a pixel during each period. In the reset period, a discharge (reset discharge) is caused between all the sustain electrodes 107X and 107Y, and wall charges are uniformly accumulated in all pixel regions. The written pixel information is deleted, and the entire screen is brought into a uniform charged state.
[0006]
In the next address period, a light emitting pixel in the display panel is selected. That is, the already accumulated wall charges are left in the light emitting pixels, and erased by discharging in the non-light emitting pixels to create a binary state (address discharge). To this end, a pulse voltage is applied to both the sustain electrode 107Y and the address electrode 103A at positions corresponding to the non-emission pixels, and the discharge is controlled.
[0007]
Specifically, sustain electrode 107Y (Y ₁ , Y ₂ , ..., Y _n ), A scanning pulse is sequentially applied to scan a pixel column, and address electrodes 103A (A) corresponding to m pixels in the scanned column. ₁ , A ₂ , ..., A _m In each case, an address pulse generated from emission / non-emission data for each pixel is applied in synchronization with the scan timing on the sustain electrode 107Y side (in this case, a pulse is applied to the non-emission pixel). This operation is usually called data writing, and the entire operation is called addressing in the sense that data is allocated to each pixel position. Further, from the role of addressing, the sustain electrode 107Y is also called a scan electrode and the address electrode 103A is also called a data electrode. Thus, in the address period, an address discharge occurs in the non-light emitting pixels, and the wall charges are erased.
[0008]
Next, in the sustain period, an AC pulse (sustain pulse) is applied to the pair of sustain electrodes 107 of all pixels. Also at this time, since the wall charges in the pixel region act as a bias, only the luminescent pixels where the wall charges remain selectively reach the discharge start voltage, and discharge (sustain discharge) is generated and maintained. Light emission is continued.
[0009]
The operation of the selective writing method is the same as that of the selective erasing method, except that the wall charges in the entire pixel region are uniformly erased by the discharge in the reset period, and the discharge is performed in the address period. It accumulates electric charge.
[0010]
[Problems to be solved by the invention]
In such a PDP, when the operation is stopped and restarted, "display unevenness" may occur on the display image, in which the pattern of the display image immediately before the stop appears as a pattern. It is considered that this is because the charged state of each pixel differs depending on whether light emission / non-light emission occurs immediately before stopping. That is, at the time of the stop, the priming particles due to the discharge remain in the area of the luminescent pixel, but such charged particles do not remain in the area of the non-luminescent pixel. This difference appears as a difference in the discharge start voltage for each pixel in the next display operation, and the brightness of the pixel depends on the display state before the stop, resulting in uneven brightness in the display image.
[0011]
By the way, in a display such as a PDP, there is a problem that if a non-operation period, that is, a period in which the display panel is left unused, is long, the pixel region in the display panel does not operate at a normal driving voltage. It is considered that this is due to the fact that the inactivation proceeds in the pixel region while the discharge is stopped. That is, the impurities generated by the discharge accumulate on the surface of sustain electrode 107 over time, and the discharge cannot be performed unless the discharge start voltage is higher. Therefore, in the PDP, a process of applying a voltage higher than a normal driving voltage to forcibly generate a discharge and activate a pixel region, that is, a so-called initialization process, is often performed before an image is displayed immediately after the power is turned on. Is done. In the initialization process, since the impurities deposited from all the pixel regions are removed, the number of pixel regions that are difficult to emit light is reduced, and the subsequent display operation can be performed smoothly.
[0012]
However, repeating such non-display discharge every time the power is turned on puts an unnecessary stress on the display panel. Moreover, at the time of initialization, a considerably high voltage must be applied in order to inactivate and discharge the pixel region in which charged particles do not remain. Conventionally, the application of a high voltage due to the initialization damages the phosphor, the dielectric, and the electrodes inside the display panel, and shortens the life of the device. Further, such a high voltage application is not preferable from the viewpoint of power consumption.
[0013]
The present invention has been made in view of such a problem, and an object of the present invention is to reduce the occurrence of display unevenness at the time of startup and to effectively perform initialization processing of a display panel and a display device. A driving circuit and a driving method are provided.
[0014]
[Means for Solving the Problems]
The display device according to any one of claims 1 to 11, further comprising: a display panel having a display surface including a plurality of pixel regions; and a driving unit that controls light emission of the display panel, and performs an operation related to display. A display device used to alternate between an operation state to be performed and a non-operation state in which an operation relating to display is stopped and a display panel is not turned on, wherein a charge state in all pixel regions of the display panel is made uniform. It has a function of performing a uniforming process.
[0015]
The drive circuit according to any one of claims 12 to 22, further comprising a display panel having a display surface including a plurality of pixel regions, an operation state in which display-related operations are performed, and a display-related operation is stopped. A driving circuit applied to a display device used to alternately take a non-operating state in which a display panel is not turned on, wherein the driving circuit applies a uniforming process to make a charging state uniform in all pixel regions of the display panel. Means.
[0016]
A driving method of a display device according to any one of claims 23 to 33, comprising: a display panel having a display surface including a plurality of pixel regions; and a driving unit that controls light emission of the display panel. A driving method of a display device used to alternately take an operation state of performing an operation relating to display and a non-operation state in which an operation relating to display is stopped and a display panel is not turned on, wherein all pixel regions of the display panel are provided. In this case, a uniformizing process for making the charged state uniform is performed.
[0017]
A display device according to any one of claims 1 to 11, a driving circuit according to any one of claims 12 to 22, or a driving circuit according to any one of claims 23 to 33. In the driving method of the display device, the charge state is uniformed over the entire surface of the display panel, that is, over the entire pixel region by the equalizing process. In each pixel area after the processing, the charged state before the processing, that is, the image information is not inherited, and the image to be displayed next time is properly displayed.
[0018]
Further, in the display device according to the second aspect, the driving circuit according to the thirteenth aspect, or the driving method of the display device according to the twenty-fourth aspect, the equalizing process is performed before entering the non-operation state. Things. In the display device, the driving circuit, or the driving method, the equalization process is performed before the display device in the operation state enters a non-operation state in which the display device is completely stopped. After the non-operation state, a change in state occurs due to the deposition of impurities in the pixel region, and it is difficult to sufficiently control the charge amount. In this case, the equalization process is performed before the non-operation state is entered.
[0019]
Furthermore, in the display device according to claim 11, the driving circuit according to claim 22, or the driving method of the display device according to claim 33, the display panel is driven immediately after entering the operation state from the non-operation state. The initialization processing for activating all the pixel regions is performed. In the display device, the driving circuit, or the driving method, while the equalizing process is performed, the initialization process is performed immediately after the display device enters the operating state from the non-operating state. In the uniforming process, when the charge state is made uniform by charge accumulation, uneven lighting of pixels in the initialization process is reduced.
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0021]
[First Embodiment]
FIG. 1 is a block diagram showing the configuration of the plasma display device according to the first embodiment of the present invention. The plasma display device 10 includes a display panel 6 and a circuit portion that controls light emission of the display panel 6 by receiving power supply from the outside. The circuit part includes a power supply unit 1 that is a voltage supply source by external power, a control unit 2 that performs control processing for display and equalization processing, a predetermined period after the connection between the power supply unit 1 and the external power supply is cut off, A backup power supply 3 for supplying power to the control unit 2 and the equalizing unit 4, a uniformizing unit 4 for performing equalizing processing on the display panel 6, and a driving unit 5 for driving the display panel 6 to perform a normal display operation It is configured. In FIG. 1, only control lines for each component are shown, and a power supply line from the power supply unit 1 is omitted.
[0022]
The power supply unit 1 receives power supply from, for example, a general household AC 100 V power supply, and generates and supplies a voltage required for driving. The power supply unit 1 has a main switch of the power supply of the device 10, and when a user turns on / off the power supply, an external power supply is performed or stopped. As a result, in the device 10, an operation state in which an operation relating to display is performed and a non-operation state in which the operation relating to display is stopped and the display panel 6 is not turned on are realized alternately. The power supply unit 1 outputs an ON signal to the control unit 2 when the switch is turned on (start of power supply) and outputs an OFF signal when the switch is turned off (stops power supply). It is supposed to.
[0023]
The control unit 2 generates and outputs a control signal to the equalizing unit 4 and the backup power supply 3 based on the on / off signal input from the power supply unit 1. That is, when an off signal is input from the power supply unit 1, the control unit 2 inputs a processing start signal to the equalization unit 4, and the equalization unit 4 uses the power from the backup power supply 3 in response to this. Then, a uniformizing process is performed. Further, when an ON signal is input from the power supply unit 1, the control unit 2 inputs a charge start control signal to the backup power supply 3 so that the backup power supply 3 stores power in preparation for the next stop. It has become.
[0024]
The backup power supply 3 supplies power to at least the control unit 2 and the equalization unit 4 so that the equalization process can be performed after the power supply from the power supply unit 1 is cut off. Therefore, as the backup power supply 3, for example, a large-capacity capacitor capable of storing a sufficient amount of power for the equalization processing can be used. Alternatively, a delay is provided (for example, several seconds) between the time when the user turns off the power supply from outside the apparatus and the time when the power supply unit 1 is actually stopped, and the power supply is made uniform within the delay period for supplying power to the plasma display apparatus 10. Processing may be performed.
[0025]
The equalizing unit 4 performs a uniforming process for equalizing a charged state in all pixel regions of the display panel 6, and is driven only when an operation signal is input from the control unit 2. Has become. This equalizing process is performed by applying the equalizing voltage V to each electrode of the display panel 6. _equ Is applied to uniformly accumulate electric charges over the entire surface of the display panel 6. Uniform voltage V _equ Is set to be equal to or higher than, for example, the discharge voltage (reset voltage) during the reset period in normal driving. As a result, the information of the display image before the equalization processing, which is stored in the display panel 6 as the charge amount for each pixel region, is deleted. Uniform voltage V _equ May be about the same as the reset discharge in a normal display operation, for example, and the voltage application time and waveform may be appropriately selected.
[0026]
In the present embodiment, a fixed amount of electric charge is accumulated on the entire surface of the display panel 6. However, in the equalizing process, the charge state may be constant, and the electric charge may be uniformly erased over the entire surface of the display panel 6. You may make it. In addition, in use in general households and the like, it takes a long time for the homogenization process to lack practicability. Therefore, it is desirable that this process be performed within a few seconds at the latest.
[0027]
The drive unit 5 is a drive circuit unit for performing display on the display panel 6. More specifically, the drive voltage V is applied to the electrodes of the display panel 6 at a predetermined timing. _dsp In this manner, a predetermined pixel of the display panel 6 is discharged, and light emission control and light emission display for each pixel are performed. The actual drive voltage has a different voltage value and waveform depending on the purpose of pixel selection and the operation of light-emitting display. However, here, for convenience, the drive voltage V _dsp Is uniquely used as “the voltage applied to the display panel 6 during the driving period”. Input of image information necessary for such display and processing thereof are realized using a circuit and a driving method configured in the same manner as in the related art, including the driving unit 5, but detailed description is omitted here. I do.
[0028]
The display panel 6 may be configured as, for example, a display panel of a general PDP. In this case, the sustain electrodes 17 (17X.17Y) are provided in parallel in pairs and intersect with the sustain electrodes 17. The address electrodes 13 are provided in parallel. The intersection area between the sustain electrode 17 and the address electrode 13 is each pixel area. A voltage is applied to the sustain electrode 17 and the address electrode 13 from one of the equalizing section 4 and the driving section 5. Uniform voltage V from uniform unit 4 _equ Is applied to, for example, (1) sustain electrode 17X, 17Y or (2) two electrodes of sustain electrode 17Y and address electrode 13, or (3) three electrodes of sustain electrode 17X, 17Y and address electrode 13.
[0029]
Here, the power supply unit 1 and the control unit 2 correspond to “state change detection unit” of the present invention, and the control unit 2 and the equalization unit 4 correspond to “uniformization unit” of the present invention.
[0030]
Next, the operation of the plasma display device 10 will be described with reference to FIGS. FIG. 2 is a flowchart illustrating an operation procedure of the device 10. FIG. 3 shows a drive sequence corresponding to this series of operations, and schematically shows a voltage waveform applied to one electrode of the display panel.
[0031]
Initially, it is assumed that the plasma display device 10 is in a power-off state and a non-operation period in which the display panel 6 does not perform a display operation continues. When the main switch of the power supply unit 1 is turned on there, power supply is started, and the device 10 is started (step S11). The power supply unit 1 outputs an ON signal to the control unit 2 at the start of power supply. When the ON signal is input, the control unit 2 inputs a charge start signal to the backup power supply 3. The backup power supply 3 stores electric power in preparation for a stop.
[0032]
The control unit 2 also starts controlling the driving unit 5 to immediately perform the display operation. The drive unit 5 applies a drive voltage V to the display panel 6 under the control of the control unit 2. _dsp And drive display is performed as usual. Thus, the device 10 enters a normal driving state (step S12). This is the beginning of an operation state for performing an operation related to display at the same time.
[0033]
Thereafter, when ending the image display, the main switch of the power supply unit 1 is turned off (step S13). The power supply unit 1 stops supplying power from the outside to the device 10 and outputs an off signal to the control unit 2. When the OFF signal is input, the control unit 2 detects that the device 10 is switched from the operation state to the non-operation state, inputs a power supply start signal to the backup power supply 3, and performs drive control for display. The operation is stopped, and an operation signal for starting the operation is input to the equalizing unit 4. When the backup power supply 3 is not used, a fixed delay time is set from the time when the main switch of the power supply unit 1 is operated to the time when the power supply is cut off, and the equalizing unit 4 is set within this delay time. Make it work.
[0034]
The equalization unit 4 to which the operation signal is input receives the power supply from the backup power supply 3 and performs the equalization process on the display panel 6 (Step S14). The uniforming process is performed by a predetermined electrode in all pixel regions of the display panel 6, for example, (1) sustain electrode 17X, 17Y or (2) two electrodes of sustain electrode 17Y and address electrode 13, or (3) sustain electrode 17X. , 17Y and the address electrode 13 are equalized voltages V _equ And discharge is performed between the electrodes to which the voltage is applied. In each of the cases (1) to (3), the equalizing voltage V _equ May be sequentially applied to each electrode as, for example, an AC pulse as shown in FIGS.
[0035]
As a result, a discharge is simultaneously generated in all the pixel regions, and after the discharge is completed, the charges are uniformly accumulated in all the pixel regions.
[0036]
The apparatus 10 is in the operating state until the equalization processing. However, when the equalization processing is completed and the power supply from the backup power supply 3 is stopped (step S15), the power supply is completely cut off and the non-operation state is established. to go into.
[0037]
When the main switch of the power supply unit 1 is turned on again and the next ON signal is input from the power supply unit 1 to the control unit 2 (step S16; Y), the device 10 enters an operation state and performs a normal drive display (step S12). ) Is repeated. In this case, electric charges are uniformly accumulated on the entire surface of the display panel 6 before driving by the homogenization process, and there is no variation in the ease of discharge between pixel regions. Therefore, the entire screen can be discharged evenly from the start of driving.
[0038]
Incidentally, such a process of making the charged state uniform over the entire screen has not been performed in the conventional plasma display device. This is because the strong discharge of the initialization process is considered to have a function of uniformly distributing the charges to a considerable extent, and it is considered that the initialization process achieves a certain degree of uniformity as well as activation of the pixel area. That's because However, the effect is inadequate and unstable to the last, and if it is desired to achieve a uniform effect in the initialization process, it is not enough to simply use the same process for removing impurities. In order to control the charge state to be strictly uniform, it is necessary to discharge sufficiently to the pixel region where no charge is accumulated, and to apply a higher voltage (or a longer time process) than the conventional initialization process. Is required. On the other hand, in the present embodiment, the charge state is controlled more reliably by performing the discharge processing for equalization separately from the initialization processing.
[0039]
Also, as the name implies, the initialization process is performed immediately after entering the operation state from the non-operation state. However, since this uniformization process is performed separately from the initialization process, the timing of the process is There is no particular limitation. Here, since the equalizing process is performed subsequent to the display operation (normal driving), the equalizing voltage V is set by the priming effect. _equ Can be easily and sufficiently discharged even if it is not as high as the discharge voltage during the initialization process.
[0040]
Furthermore, since the uniformization process accumulates electric charges in all pixel regions, it has an effect of making discharge more likely to occur. In the subsequent non-operating state, it is considered that inactivation proceeds in each pixel region. However, by accumulating charges before that, the discharge load at the time of restarting is reduced because discharge becomes easier to start. . Therefore, it is expected that the uniforming process contributes to smooth driving display.
[0041]
As described above, according to the present embodiment, the control unit 2 detects that the display operation is stopped and the non-operating state is entered by turning off the main switch of the power supply unit 1 and before the non-operating state is entered. In addition, the equalizing unit 4 applies the equalizing voltage V to the display panel 6 as the equalizing process. _equ Is applied, the electric charge is uniformly accumulated in all the pixel regions by the discharge generated, so that the charge state of each pixel region is equalized by the accumulated electric charges in the display panel 6 at the time of the restart. Therefore, at the time of restarting, the entire screen can be discharged evenly from the time of driving start, and display unevenness can be prevented. Generally, when the pixel passes through the non-operating state, a state change due to deposition of impurities in the pixel region occurs, so that it is difficult to easily perform such charge amount control. Since it is performed before entering, it is possible to easily and surely equalize the charge amount in all pixel regions.
[0042]
In the present embodiment, the electric charge is accumulated in each pixel area by the equalization processing. However, the equalization processing is performed to make the charged state uniform, and the equalization processing is performed uniformly from all the pixel areas. The charge may be erased.
[0043]
[Second embodiment]
FIG. 7 is a block diagram illustrating a configuration of a plasma display device according to the second embodiment of the present invention. The plasma display device 20 performs the equalization process using a drive circuit for normal display, and does not include a drive circuit for only the equalization process separately from a normally provided drive circuit. . That is, the plasma display device 20 has the same configuration as that of the plasma display device 10 of the first embodiment except that the homogenizing unit 4 is not provided. Therefore, the same reference numerals are given to the same components, and the description thereof will be appropriately omitted.
[0044]
Although not described in detail in the first embodiment, each of the plasma display devices 10 and 20 is provided with an image processing unit 7. In such a display device, usually, a video signal such as an NTSC signal input externally is digitized and subjected to various kinds of signal processing to finally generate a data signal as bit data corresponding to each pixel of the display panel 6. However, here, the video processing unit 7 performs such a function. The data signal generated by the video processing unit 7 based on the video signal is output to the driving unit 5. The drive unit 5 generates a drive voltage corresponding to the input data signal, and applies the drive voltage to the address electrode 13 in response to the scan of the sustain electrode 17Y during addressing. At the time of normal driving, the light emission / non-light emission information of each pixel is written into the corresponding pixel area as a change in the charge state due to the address discharge, and an image input as a video signal is displayed on the screen of the display panel 6. It has become.
[0045]
The video processing unit 7 of the present embodiment further includes a data signal S for uniforming processing. _w (Bit data of “1” for all pixel regions) is also generated and output to the drive unit 5. That is, the equalization process is performed by the operation in the case of full white display in which the entire screen emits light in normal driving display. This is because the electric charge state can be made uniform by discharging in all the pixel regions. Specifically, a series of discharge operations for displaying one screen, a reset discharge, an address discharge, and a sustain discharge are performed, but the address discharge is not a data signal derived from a video signal, unlike during normal driving. Data signal S _w It is performed based on.
[0046]
Further, the control unit 2 sends a control signal S to the video processing unit 7 during the equalization processing. _c Is output, and the operation of the entire equalizing process is controlled. The video processing unit 7 controls the control signal S _c Data signal S according to the input of _w Generate and output Here, the control unit 2 and the video processing unit 7 correspond to “uniformizing means” of the present invention.
[0047]
Next, the operation of the plasma display device 20 will be described with reference to FIG. 7, FIG. 8, and FIG. FIG. 8 is a flowchart showing the operation procedure of the device 20. FIG. 9 shows a driving sequence corresponding to this series of operations, and schematically shows a voltage waveform applied to one electrode of the display panel.
[0048]
Initially, it is assumed that the plasma display device 20 is in a power-off state and a non-operation period in which the display panel 6 does not perform a display operation continues. When the main switch of the power supply unit 1 is turned on there, power supply is started, and the device 20 is started (step S21).
[0049]
The power supply unit 1 outputs an ON signal to the control unit 2 at the start of power supply. When the ON signal is input, the control unit 2 starts controlling the driving unit 5 to perform the display operation immediately. The drive unit 5 applies a drive voltage V to the display panel 6 under the control of the control unit 2. _dsp And drive display is performed as usual (step S22). At this time, writing of display data to each pixel region is performed by an addressing operation based on a display signal input from the video processing unit 7 to the driving unit 5. Thus, the device 20 enters an operation state in which an operation related to display is performed.
[0050]
Thereafter, when ending the image display, the main switch of the power supply unit 1 is turned off (step S23). The power supply unit 1 stops supplying power from the outside to the device 10 and outputs an off signal to the control unit 2. When the OFF signal is input, the control unit 2 detects that the device 20 is switched from the operation state to the non-operation state, inputs a power supply start signal to the backup power supply 3, and performs drive control for display. After stopping, the drive unit 5 and the video processing unit 7 are again subjected to drive control for the equalization process.
[0051]
First, the drive unit 5 applies the reset pulse RP to all the sustain electrodes 17X and 17Y of the display panel 6 as in the case of the normal drive, and performs the reset discharge in all the pixel regions (step S24). As a result, charge erasure or wall charge accumulation is performed on all pixel regions.
[0052]
The control unit 2 sends a control signal S to the video processing unit 7. _c Is sent. The video processing unit 7 controls the control signal S _c Is input to the drive unit 5, the data signal S of the white display is displayed on the entire surface. _W Is output. The driving unit 5 receives the data signal S _w , An address pulse AP for performing writing so as to select all pixels as light-emitting pixels is generated and applied to the address electrode 13 at the next addressing. That is, addressing is performed in the case of full white display in normal driving (step S25). When the charge is erased at the time of reset, an address discharge is performed on all the pixel regions to accumulate the charges. Further, in the case of the driving method in which electric charges are accumulated at the time of resetting, wall charges are already accumulated in all pixel regions, and substantially no address discharge occurs here.
[0053]
Next, the driving unit 5 applies a sustain pulse SS to all the sustain electrodes 17X and 17Y to generate a sustain discharge in all pixel regions at the same time as in the normal sustain period (step S26). As a result, charges are uniformly accumulated in each pixel region. Note that the discharge at this time is maintained for a period sufficient to uniformly accumulate charges in each pixel region.
[0054]
When the above equalization processing is completed, the power supply from the backup power supply 3 stops (step S27). As a result, the power supply of the device 20 is completely cut off, and the device 20 enters the non-operation state from the operation state.
[0055]
When the main switch of the power supply unit 1 is turned on again, and the next ON signal is input from the power supply unit 1 to the control unit 2 (step S28; Y), the device 20 enters the operation state, and the normal drive display (step S22) ) Is repeated. In this case, electric charges are uniformly accumulated on the entire surface of the display panel 6 before driving by the homogenization process, and there is no variation in the ease of discharge between pixel regions. Therefore, the entire screen can be discharged evenly from the start of driving.
[0056]
As described above, according to the present embodiment, before entering the non-operation state, by performing the all-white screen display as the equalization processing, the discharge is generated in all the pixel regions, and the charges are uniformly accumulated. Therefore, in the display panel 6 at the time of the restart, the charge state of each pixel region is equalized by the accumulated charge. Therefore, also in the present embodiment, the uniforming process can be easily and reliably performed, and at the time of restarting, the entire screen can be uniformly discharged from the start of driving, thereby preventing display unevenness. Can be.
[0057]
Further, in the present embodiment, the control signal S _c Is input to the video processing unit 7, and the all-white data signal S _w Is performed by the same operation as in the normal driving display except that is input to the driving unit 5, so that there is no need to separately provide a driving circuit for uniform processing. Therefore, a plasma display device that performs the homogenization process can be realized with a simple configuration and at a reduced cost. In the present embodiment, the electric charge is accumulated in each pixel region by the equalizing process. However, the operation of black display on the entire surface may be performed to erase the electric charge uniformly from each pixel region. Good.
[0058]
[Third Embodiment]
FIG. 10 is a block diagram illustrating a configuration of a plasma display device according to the third embodiment of the present invention. The plasma display device 30 performs a uniforming process before entering a non-operation state, and performs an initialization process for activating the display panel 6 when entering an operation state. The configuration is such that an initialization unit 8 is further provided in the plasma display device 10 of the embodiment. Therefore, the same components as those of the plasma display device 10 are denoted by the same reference numerals, and the description thereof will be appropriately omitted.
[0059]
Here, in addition to the control operation described in the first embodiment, the control unit 2 performs an initialization process when an ON signal is input from the power supply unit 1, and inputs an operation signal to the initialization unit 8. It is supposed to.
[0060]
The initialization unit 8 performs an initialization process for activating the display panel 6. Here, the initialization unit 8 is driven only when an operation signal is input from the control unit 2. The initialization process in this case is performed, for example, by applying a normal drive voltage V to each electrode of the display panel 6. _dsp Initialization voltage V higher than _int Is applied, the first discharge after a relatively long blank period in a non-operating state is forcibly generated in all the pixel regions. In the initialization process, the inside of each pixel region is activated by discharging an impurity on a protective layer (not shown) or supplying priming particles by discharging. Initialization voltage V at this time _int Is required and sufficient to forcibly discharge the entire surface of the display panel 6 in an inactive state, and the voltage application time and waveform may be appropriately selected. Note that the initialization voltage V _int Is applied, for example, at the time of the homogenization process in the first embodiment. _equ , (1) sustain electrodes 17X and 17Y or (2) sustain electrodes 17Y and address electrodes 13, or (3) sustain electrodes 17X and 17Y and address electrodes 13. The driving waveform for each electrode may be the same AC pulse. The initialization process also lacks practicality if it takes time, so it is desirable to keep it within a few seconds at the latest.
[0061]
Next, the operation of the plasma display device 30 will be described with reference to FIG. 10, FIG. 11, and FIG. FIG. 11 is a flowchart showing an operation procedure of the device 30, and FIG. 12 is a drive sequence corresponding to this series of operations.
[0062]
Initially, it is assumed that the plasma display device 30 is in a power-off state and a non-operation period in which the display panel 6 does not perform a display operation continues. When the main switch of the power supply unit 1 is turned on, the power supply is started, and the device 30 is started (step S31).
[0063]
The power supply unit 1 starts power supply and outputs an ON signal to the control unit 2. When an ON signal is input, the control unit 2 inputs an operation signal for starting operation to the initialization unit 8. The initialization unit 8 receives the operation signal and performs an initialization process on the display panel 6 (Step S32). Specifically, the initialization unit 8 applies an initialization voltage V to a predetermined electrode on the display panel 6. _int To generate a discharge. Accordingly, the inside of the display panel 6 is activated by removing impurities on the electrode surface or generating priming particles, and thereafter the display panel 6 is driven smoothly. Also, here, the device 30 enters the operating state with the initialization process.
[0064]
After the initialization process, the device 30 enters a normal driving state (step S33). The control unit 2 starts controlling the driving unit 5 so as to immediately perform driving for display. The drive unit 5 applies a drive voltage V to the display panel 6. _dsp And driving is performed as usual, and display is performed.
[0065]
The subsequent operation of the device 30 is the same as that of the device 10 according to the first embodiment. That is, when the main switch of the power supply unit 1 is turned off to end the image display (step S34), the power supply unit 1 stops the power supply and outputs an off signal to the control unit 2. When the OFF signal is input, the control unit 2 detects that the device 30 is switched from the operating state to the non-operating state, inputs a power supply start signal to the backup power supply 3, and performs drive control for display. The operation is stopped, and an operation signal for starting the operation is input to the equalizing unit 4. The equalization unit 4 to which the operation signal has been input performs equalization processing on the display panel 6 (Step S35).
[0066]
The equalizing process is performed by applying the equalizing voltage V to predetermined electrodes in all pixel regions of the display panel 6. _equ And discharge is performed. In this way, a discharge is simultaneously generated in all the pixel regions, and after the discharge is completed, the charged state of each pixel region is equalized by the accumulated charge.
[0067]
Further, the apparatus 30 is in an operating state until the equalization processing. However, when the equalization processing is completed and the power supply from the backup power supply 3 is stopped (step S36), the power supply is completely cut off and the non-operation state is established. to go into.
[0068]
When the main switch of the power supply unit 1 is turned on again and the next ON signal is input from the power supply unit 1 to the control unit 2 (step S37; Y), the device 30 enters an operation state and initialization processing (step S32). Are repeated.
[0069]
In the display panel 6 that has just entered the operating state, the electric charges are uniformly accumulated on the entire surface by the equalization processing, and the state in which the discharge is easy does not vary from pixel area to pixel area. In the present embodiment, the display panel 6 in this state is subjected to an initialization process. This makes it possible to discharge the entire screen evenly and reliably from the start of driving.
[0070]
Note that performing the equalization process at the end of the operation state and accumulating the electric charges in all the pixel regions has an effect of easily causing the next discharge. Therefore, in the initialization processing here, it is possible to discharge even if the voltage is not as high as the conventional one, so that the initialization voltage V _int To reduce the discharge intensity. Furthermore, the uniformization voltage V of the uniformization process _equ Is set somewhat higher (for example, higher than the reset voltage), the effect of reducing the initialization processing is emphasized.
[0071]
As described above, according to the present embodiment, the display panel 6 is subjected to the equalization processing and the initialization processing before and after the display operation, respectively. Therefore, in addition to the effects described in the first embodiment, The following effects are exhibited. That is, since the charge is accumulated before entering the non-operation state by the equalization processing, discharge is likely to occur in all the pixel regions, and the discharge intensity of the initialization processing performed immediately after the operation state is re-entered is reduced. Can be. The conventional initialization process has to be performed at a high pressure and has a problem such as damage to the display panel. _int Is set lower, it is possible to suppress damage to the display panel 6 and to greatly alleviate its deterioration.
[0072]
In addition, the uniformized voltage V _equ Is about the normal drive voltage, and the initialization voltage V _int Therefore, it is also possible to reduce the power consumption in the entire operation period. Note that the equalization processing of the present embodiment is the same as the equalization processing of the first embodiment, but may be similar to the second embodiment.
[0073]
Note that the present invention is not limited to the above embodiment, and various modifications can be made. For example, in the above-described embodiment, only the case where the equalization processing is performed immediately before the end of the operation state has been described, but this does not limit the timing of the equalization processing of the present invention.
[0074]
Further, although the plasma display device has been described in the above embodiment, the present invention is not limited to the plasma display device, and may be applied to a display device in which the display operation immediately before the stop affects the image display at the time of restart. Can be.
[0075]
Further, the homogenization processing according to the present invention may be applied solely for the purpose of reducing the device load in the initialization processing, and in this case, it can be applied to all display devices using electron emission. In such a display device, the charge state inside the display panel changes over time while the display device is left without performing a display operation. Therefore, some kind of initialization processing for restoring the charged state at the time of restart is effective. However, according to the present invention, as described in the third embodiment, the adverse effects associated with the initialization processing are reduced. be able to. In this case, as a display device to be applied, a plasma address liquid crystal (PALC) display device using a plasma discharge for an electronic switch, a field emission display (FED), a fluorescent display tube (VFD: Vacuum Fluorescent Display).
[0076]
【The invention's effect】
As described above, the display device according to any one of claims 1 to 11, the drive circuit according to any one of claims 12 to 22, or the one according to claims 23 to 33 According to the driving method of the display device described in the above, since the uniforming process is performed to uniform the charging state in all the pixel regions of the display panel, the charging state of each pixel region is equalized, the image before processing Information is not carried over. Therefore, at the time of displaying the next image, it is possible to prevent the image displayed at the end of the previous operation state from appearing unevenly, and to appropriately display the image to be displayed on the entire screen.
[0077]
In particular, according to the display device described in claim 2, the driving circuit described in claim 13, or the driving method of the display device described in claim 24, the state of the device itself is changed from the operating state to the non-operating state. When switching, the equalization processing is performed before entering the non-operation state, so that the equalization processing can be performed easily and reliably compared to after the state change occurs in the pixel area through the non-operation state. It becomes possible.
[0078]
In particular, according to the display device of claim 11, the driving circuit of claim 22, or the driving method of the display device of claim 33, the display panel is driven immediately after entering the operation state from the non-operation state. Since the initialization processing for activating all the pixel areas is performed, when the equalization processing is performed by charge accumulation, the initialization processing is easily performed by the charge remaining in each pixel area at the time of restart. Therefore, the initialization process in this case requires less processing than in the past, and the original operation and effect of reliably displaying the display pixels while significantly reducing damage to the display panel can be sufficiently exhibited. Can be. That is, it is possible to improve display quality such as display unevenness, prevent deterioration of the display panel, and extend the life of the display panel. At the same time, by lowering the intensity of the initialization processing, power consumption can be suppressed as compared with the case where the conventional initialization processing is performed.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a plasma display device according to a first embodiment of the present invention.
FIG. 2 is a flowchart for explaining the operation of the plasma display device shown in FIG.
FIG. 3 is a voltage waveform diagram showing a driving sequence of the plasma display device shown in FIG.
FIG. 4 is a waveform diagram showing an example of a drive voltage applied during a uniforming process in the drive sequence of FIG.
FIG. 5 is a waveform diagram showing an example of a drive voltage applied during the equalization process in the drive sequence of FIG.
FIG. 6 is a waveform diagram showing an example of a drive voltage applied during the equalization process in the drive sequence of FIG.
FIG. 7 is a block diagram illustrating a configuration of a plasma display device according to a second embodiment of the present invention.
FIG. 8 is a flowchart illustrating an operation of the plasma display device shown in FIG. 7;
9 is a voltage waveform diagram showing a driving sequence of the plasma display device shown in FIG.
FIG. 10 is a block diagram showing a configuration of a plasma display device according to a third embodiment of the present invention.
11 is a flowchart illustrating an operation of the plasma display device shown in FIG.
FIG. 12 is a voltage waveform diagram showing a driving sequence of the plasma display device shown in FIG.
FIG. 13 is a perspective view showing a configuration of a display panel of a conventional plasma display device.
14 is a configuration diagram illustrating an electrode arrangement of the display panel illustrated in FIG.
15 is a voltage waveform diagram showing a driving sequence of the plasma display device shown in FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Power supply part, 2 ... Control part, 3 ... Backup power supply, 4 ... Equalization part, 5 ... Drive part, 6 ... Display panel, 7 ... Video processing part, 8 ... Initialization part, 10, 20, 30 ... Plasma Display device, V _equ ... Equalizing voltage, V _dsp ... Drive voltage, V _int ... Initialization voltage.

Claims (33)

A display panel having a display surface composed of a plurality of pixel regions, and a drive unit for controlling light emission of the display panel, an operation state of performing an operation relating to display, an operation relating to display is stopped, and the display panel is not turned on A display device used to alternately take a non-operating state,
A display device having a function of performing a uniforming process for making a charged state uniform in all pixel regions of the display panel. The display device according to claim 1, wherein when the own state switches from the operation state to the non-operation state, the equalization processing is performed before the non-operation state is entered. Configured as a plasma display device,
2. The display device according to claim 1, wherein all pixel regions of the display panel are discharged as the equalizing process. The display panel includes first and second substrates that are opposed to each other, a sustain electrode that is provided in parallel on the opposite surface of the first substrate in a pair, and an opposite surface of the second substrate. The display device according to claim 3, further comprising: an address electrode provided so as to intersect and be parallel to the sustain electrode. 5. The display device according to claim 4, wherein the equalization processing is performed by discharging an entire pixel region between the pair of sustain electrodes. 6. 5. The display device according to claim 4, wherein the equalization processing is performed by discharging an entire pixel area between one of the pair of sustain electrodes and the address electrode. 6. 5. The display device according to claim 4, wherein the uniforming process is performed by discharging an entire pixel region between the pair of sustain electrodes and the address electrodes. 6. A reset operation for discharging all pixel areas in order to equalize the charge state in one screen display,
An address operation of discharging each pixel region according to light emission / non-light emission in order to selectively cause charged particles for discharge to stay only in the pixel region to be light-emitting;
In order to perform image display, a sustain operation for discharging only a pixel area selected in advance as a light emitting pixel is performed, and
The display device according to claim 3, wherein the equalization processing is performed by a series of operations of the reset operation, the address operation, and the sustain operation. 9. The display device according to claim 8, wherein the uniforming process is performed by selecting all pixel regions as pixel regions to emit light in the address operation and displaying an all-white screen. 10. 9. The display device according to claim 8, wherein the equalization processing is performed by selecting all the pixel areas as non-light emitting pixel areas in the address operation and displaying an all black screen. further,
The display device according to claim 1, further comprising a function of performing an initialization process for activating all pixel regions of the display panel immediately after entering the operation state from the non-operation state. A display panel having a display surface composed of a plurality of pixel areas is provided, and is used so as to alternately take an operation state in which an operation relating to display is performed and a non-operation state in which the operation relating to display is stopped and the display panel is not turned on. A driving circuit applied to a display device,
A drive circuit comprising a uniforming means for performing a uniforming process for equalizing a charged state in all pixel regions of the display panel. 13. The drive circuit according to claim 12, further comprising a state change detecting unit that detects that a state of the display device is switched from the operation state to the non-operation state. The display device is configured as a plasma display device,
13. The driving circuit according to claim 12, wherein the equalizing unit discharges all pixel regions of the display panel. The plasma display device, a display panel,
First and second substrates arranged to face each other, a sustain electrode provided in parallel on the facing surface of the first substrate in a pair, and a sustain electrode provided on the facing surface of the second substrate. 15. The driving circuit according to claim 14, further comprising: an address electrode provided so as to intersect and be arranged in parallel. 16. The drive circuit according to claim 15, wherein the equalizing unit performs the equalizing process by applying a predetermined voltage to each of the pair of sustain electrodes. 16. The drive circuit according to claim 15, wherein the equalizing unit performs the equalizing process by applying a predetermined voltage to one of the pair of sustain electrodes and the address electrode. 16. The driving circuit according to claim 15, wherein the equalizing unit performs the equalizing process by applying a predetermined voltage to the pair of sustain electrodes and the address electrodes. The uniformizing means includes:
A reset operation for discharging the entire pixel area in order to make the charge state uniform,
An address operation of discharging each pixel region according to light emission / non-light emission in order to selectively cause charged particles for discharge to stay only in the pixel region to be light-emitting;
In order to perform image display, a single screen display is performed by performing a sustain operation of discharging only a pixel region selected in advance as a light emitting pixel, and
15. The drive circuit according to claim 14, wherein the equalization processing is performed by a series of operations of the reset operation, the address operation, and the sustain operation. 20. The drive circuit according to claim 19, wherein the equalizing unit selects all pixel regions as pixel regions to emit light in the address operation. 20. The driving circuit according to claim 19, wherein the equalizing unit selects all the pixel regions in the address operation as pixel regions that do not emit light. further,
13. The driving circuit according to claim 12, wherein an initialization process for activating all pixel regions of the display panel is performed immediately after the start of the operation state. A display panel having a display surface made up of a plurality of pixel regions; and a drive unit for controlling light emission of the display panel, an operation state of performing an operation related to display, and an operation state related to display stopped, and the display panel is turned on. A method of driving a display device used to alternately take a non-operating state that is not performed,
A driving method for a display device, comprising: performing a uniforming process for making a charged state uniform in all pixel regions of the display panel. 24. The display device according to claim 23, wherein the state of the display device is detected to be switched from the operation state to the non-operation state, and the equalization process is performed before the start of the non-operation state. Drive method. When the display device is a plasma display device,
24. The method according to claim 23, wherein the entire display surface of the display panel is discharged as the uniforming process. Further, the display panel includes first and second substrates arranged to face each other, a sustain electrode provided in parallel on the facing surface of the first substrate in pairs, and a display panel of the second substrate. 26. The method of driving a display device according to claim 25, wherein the method is applied to a plasma display device comprising: an address electrode provided on an opposing surface so as to intersect and be parallel to the sustain electrode. 27. The method according to claim 26, wherein the equalizing process is performed by discharging between the pair of sustain electrodes. 27. The method according to claim 26, wherein the equalizing process is performed by discharging between one of the pair of sustain electrodes and the address electrode. 27. The method according to claim 26, wherein the equalizing process is performed by discharging between the pair of sustain electrodes and the address electrodes. In addition, one screen display,
A reset operation for discharging the entire pixel area in order to make the charge state uniform,
An address operation of discharging each pixel region according to light emission / non-light emission in order to selectively cause charged particles for discharge to stay only in the pixel region to be light-emitting;
In order to perform image display, a sustain operation for discharging only a pixel area selected in advance as a light emitting pixel is performed, and
26. The method according to claim 25, wherein the equalization processing is performed by a series of operations of the reset operation, the address operation, and the sustain operation. The homogenization process,
31. The driving method of a display device according to claim 30, wherein the address operation is performed by selecting all the pixel regions as pixel regions to emit light and displaying an all-white screen. The homogenization process,
31. The driving method of a display device according to claim 30, wherein in the address operation, all pixel regions are selected as non-light emitting pixel regions and an all black screen is displayed. further,
24. The method according to claim 23, wherein an initialization process for activating all pixel regions of the display panel is performed immediately after entering the operating state from the non-operating state.

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