JP3642170B2 - Plasma display panel temperature control method and plasma display apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a plasma display panel temperature control method and a plasma display apparatus.
[0002]
[Prior art]
FIG. 17 is a block diagram showing a configuration of a conventional plasma display device disclosed in, for example, Japanese Patent Laid-Open No. 9-6283. In the figure, reference numeral 101 denotes a plasma display panel (PDP), which includes address electrodes A1 to AM for performing address discharge, X electrodes X1 to XN and Y electrodes Y1 to YN for performing sustain discharge. Reference numeral 102 denotes a predetermined signal (dot clock CLK, display data DATA, vertical synchronization signal VSYNC, horizontal synchronization signal HSYNC) and a later-described address driver 103, X common driver 104, Y-scan driver 106, based on the control of the microcomputer 190. A control circuit that drives the PDP 101 by controlling the Y common driver 107, and includes a display data control unit 111 and a panel drive control unit 112, which will be described later. An address driver 103 applies an address pulse PAA and a write pulse PAW to the address electrodes A1 to AM based on a control signal SA from the control circuit 102, and 104 is based on a control signal SX from the control circuit 102. An X common driver that applies a write pulse PXW and a sustain pulse PXS to the X electrodes X1 to XN. 105 is a thermocouple that detects the temperature of the X common driver 104 and outputs a detection signal STX to the microcomputer 190 described later. 106 is a Y scan driver for applying a scan pulse PAY to Y electrodes Y1 to YN based on a control signal SYS from the control circuit 102, and 107 is a control signal SYC from the control circuit 102. Based on the Y electrodes Y1 to YN via the Y scan driver 106 A Y common driver for applying a sustain pulse PYS Te. Reference numeral 108 denotes a temperature detector such as a thermocouple which detects the temperature of the Y common driver 107 and outputs a detection signal STY to a microcomputer 190 which will be described later. 109 is a PDP 101 which is controlled by the microcomputer 190 which will be described later when starting up. A panel heating device such as a heater that heats the PDP 101 when the temperature is low, and a temperature detector 110 detects the temperature of the PDP 101 and outputs a detection signal STP to the microcomputer 190 described later. Reference numeral 111 divides frame data corresponding to one frame in the display data DATA into a plurality of subframe data based on the control of the dot clock CLK, the display data DATA, and the microcomputer 190, and addresses the control signal SA based on the subframe data. This is a display data control unit that outputs to the driver 103, and includes a frame memory 120, a subtractor 121, and a frame memory 122, which will be described later.
[0003]
112 is a panel drive control that outputs control signals SYS, SYNC, and SX to the Y scan driver 106, Y common driver 107, and X common driver 104, respectively, based on the vertical synchronization signal VSYNC, horizontal synchronization signal HSYNC, and control of the microcomputer 190. A scan driver control unit 130 and a common driver control unit 131, which will be described later. Reference numerals 120 and 122 denote frame memories that temporarily store the input display data DATA by one frame at a time. While the display data is being written to either one of 120 and 122, the other is written earlier. Display data is read out. A subtractor 121 corrects the number of gradations of the display data DATA stored in the frame memories 120 and 122 under the control of the microcomputer 190. Reference numeral 130 denotes a scan driver control unit, and reference numeral 131 denotes a common driver control unit. A voltage conversion unit 140 applies high voltage power to each driver, and includes a Vc power supply unit 141, a Vw power supply unit 142, a Vsc power supply unit 143, a Vy power supply unit 144, and a Vx power supply unit 145. Reference numeral 150 denotes an EP-ROM, which stores in advance a waveform of each pulse applied to the PDP 101 and outputs a desired pulse waveform under the control of a microcomputer 190 described later, and a sustain pulse number setting area 150B. Have Reference numeral 160 denotes an internal atmosphere temperature detector that detects an atmospheric temperature in the apparatus and outputs a detection signal to a microcomputer 190 described later. Reference numeral 170 denotes an LED that displays a warning. Reference numeral 171 denotes a control of the microcomputer 190 described later. , A control circuit for controlling the display of the LED 170, 180 is an air cooling device for cooling the entire device, 181 is a control circuit for controlling the operation of the air cooling device 180 under the control of the microcomputer 190 described later, 191 A relay control unit that prohibits the application of a high voltage to the voltage conversion unit 140 and the control circuit 102 under the control of the microcomputer 190, which will be described later, and 192 is a power consumption detection unit that detects the power consumption of the entire plasma display device. , 190 is a microcomputer.
[0004]
Next, the operation will be described. Display data DATA input to the control circuit 2 from the display data input unit is stored in one of the frame memories 120 and 122. The data on the frame memory is divided and read for each subframe in order to perform multi-gradation display. In the case of 256 gradation display, one frame is divided into 8 subframes, and the light emission time of each subframe is set to 1: 2: 4: 8: 16: 32: 64: 128. The gradation of 0 to 255 is expressed by a combination of non-light emission. First, an operation when displaying a subframe corresponding to a light emission time of 128 will be described with reference to FIG. FIG. 18 is a timing chart showing the operation of one subframe of the conventional plasma display device.
[0005]
First, all display cells are erased during the reset period. The reset period is composed of an entire writing period and a self-erasing period. First, in the entire writing period, the levels of all the Y electrodes Y1 to YN are first set to 0 V, and the writing pulse PXW is applied to all the X electrodes X1 to XN. The write pulse PAW is applied to all the address electrodes A1 to AM in synchronization with the write pulse PXW. By the write pulses PXW and PAW, discharge is performed between all the X electrodes X1 to XN and all the address electrodes A1 to AM. Thereafter, by setting the levels of all the X electrodes X1 to XN and all the address electrodes A1 to AM to 0 V in the self-erasing period, discharging is performed until the wall charges disappear in all the display cells, and the erasing is completed. .
[0006]
Next, in the address period, only the cells that should emit light are discharged to accumulate wall charges. A scan pulse PAY is applied to the Y electrode in a time-sharing manner from Y1 to YN sequentially. In parallel with this, based on subframe data corresponding to a light emission time of 128, among the address electrodes A1 to AM, light should be emitted. An address pulse PAA is applied to the address electrode corresponding to the cell. During the address period, all X electrodes X1 to XN are maintained at a predetermined X address voltage. As a result, first, a priming address discharge is generated between the Y electrode corresponding to the cell to emit light and the address electrode, and this is used as a priming, and the main address discharge is generated between the corresponding X electrode and Y electrode. As a result, wall charges are accumulated.
[0007]
Finally, in the sustain discharge period, discharge is continuously performed so that the light emission time becomes 128 in the light emitting cell specified in the address period. Pulses PXS and PYS are alternately applied to all X electrodes and Y electrodes, and a sustain discharge is performed in the light emitting cells in which wall charges are accumulated in the address period, and display is performed. Here, as the number of sustain pulses PXS and PYS increases, the luminance in the subframe increases.
[0008]
A subframe corresponding to a light emission time of 128 is displayed by the sequence including the reset period, the address period, and the sustain discharge period. Subsequently, by similarly displaying the sub-frames with the light emission times of 64, 32, 16, 8, 4, 2, 1 and so on, one frame of video can be displayed with 256 gradations.
[0009]
In the conventional plasma display device configured as described above, the surface temperature of the PDP 101 is detected by the temperature detector 110. The temperatures of the X common driver 104 and the Y common driver 107 are detected by the temperature detectors 105 and 108. Here, the luminance of the PDP 101 decreases in proportion to the temperature increase of the PDP 101 and decreases in proportion to the temperature increase of the X common driver 104 and the Y common driver 107. By using the respective proportionality constants obtained in advance by measurement and processing the detection signals STP, STX, and STY obtained from the temperature detectors 110, 105, and 108 by the microcomputer 190, the decrease in luminance can be obtained. The microcomputer 190 performs control so as to increase the luminance so as to correct the decrease in luminance. As a method for increasing the luminance, there are a method for controlling the number of pulses, a method for controlling the sustain voltage, and a method for controlling the display data section as described below.
[0010]
The method for controlling the number of pulses utilizes the fact that the number of sustain pulses is proportional to the brightness of the PDP 101. The microcomputer 190 calculates the number of sustain pulses that corrects a decrease in luminance due to temperature change, and uses the result as a selection address signal in the sustain pulse number setting area 150B in the EP-ROM 150. In the EP-ROM 150, the number of sustain pulses for each subfield with respect to the reference number of sustain pulses is set, and based on this, the number of sustain pulses corrected in each subfield is output to the panel drive control unit 112. The common driver control unit 131 of the panel drive control unit 112 outputs a sustain pulse corresponding to the corrected number of sustain pulses, and corrects a decrease in luminance due to a temperature increase of the PDP 101 and each driver.
[0011]
Next, the method of controlling the sustain voltage uses the fact that the voltages of the sustain pulses PXS and PYS (sustain discharge voltage VS) and the brightness of the PDP 101 are proportional. Since the microcomputer 190 is connected to the sustain discharge voltage reference voltage output unit OUT, and thereby the sustain discharge voltage VS can be controlled, the microcomputer 190 compensates for a decrease in luminance due to a temperature change. The voltage is calculated, and the result is output from the sustain discharge voltage reference voltage output unit OUT to the external high voltage generator and becomes the reference for the voltage value to be input to the driving high voltage input unit INV. The sustain discharge voltage VS is set by the driver control unit 131, and the luminance decrease due to the temperature increase of the PDP 101 and each driver is corrected.
[0012]
Further, the method for controlling the display data portion utilizes the fact that the gradation value of the display data DATA is proportional to the luminance of the PDP 101. The microcomputer 190 is connected to the display data control unit 111, and the display data control unit 111 subtracts the gradation value of each light emitting cell based on the subtraction data of the microcomputer 190. Display data DATA input from the display data input unit IN in the vertical synchronization period n is stored and held in the frame memory 120. In the next vertical synchronization period n + 1, the gradation value for luminance correction is subtracted from the data in the frame memory 120 via the subtracter 121, and then output to the address driver 103 as display data included in the control signal SA, and an image is displayed on the PDP 101. Is displayed. The display data DATA input from the display data input unit IN in the vertical synchronization period n + 1 is stored and held in the frame memory 122. The display data is processed by causing the two frame memories 120 and 122 to perform the above operation alternately, and the series of operations corrects a decrease in luminance due to a temperature increase.
[0013]
Further, in the conventional plasma display apparatus configured as described above, the temperature of the plasma display apparatus including the PDP 101 when the ambient environment temperature in which the PDP 101 is operated is abnormally high or when an unexpected failure occurs. Can be operated to prevent this when the temperature rating of the circuit element exceeds the temperature rating of the circuit element and there is a possibility that the circuit element may lead to component destruction. The surface temperature of the PDP 101 and the temperatures of the X common driver 104 and the Y common driver 107 are detected by temperature detectors 110, 105, and 108, and detection signals STP, STX, and STY are output to the microcomputer 190. In addition, the atmospheric temperature in the apparatus is detected by the apparatus internal temperature detector 160 and is output to the microcomputer 190. When at least one of the temperature information obtained by the above detection signals exceeds a threshold value set for each, the microcomputer 190 performs control to protect the plasma display device. Specifically, there are a method of performing an air cooling process by operating an air cooling device 180 such as a fan, a method of warning the user by blinking an LED, and a method of prohibiting power supply to the plasma display device.
[0014]
In the method of performing the air cooling process, when any one of the temperature information (detection signals STP, STX, STY, detection output of the atmospheric temperature detector in the apparatus) input to the microcomputer 190 exceeds the threshold, the microcomputer 190 Based on the result, the air cooling device 180 is operated via the control circuit 181. This operation is continued until all of the temperature information input to the microcomputer 190 falls below the threshold value.
[0015]
Further, in the method of warning by blinking the LED, when any one of the temperature information input to the microcomputer 190 exceeds the threshold, the microcomputer 190 causes the LED 170 to blink via the control circuit 171 based on the result. . This operation is continued until all of the temperature information input to the microcomputer 190 falls below the threshold value.
[0016]
Further, in the method of prohibiting power supply to the plasma display device, when any one of the temperature information input to the microcomputer 190 exceeds a threshold value, the microcomputer 190 operates the relay control unit 191 based on the result, Temporarily cut off the drive high-voltage line. This operation is continued until all of the temperature information input to the microcomputer 190 falls below the threshold value.
[0017]
With the above operation, the plasma display device can be protected when the temperature of the plasma display device including the PDP 101 rises abnormally.
[0018]
In such a conventional plasma display device, the change in the discharge characteristic of the PDP and the change in the driver characteristic due to the temperature rise are corrected, and the display characteristic is not affected even if the temperature of the PDP and the driver rises. Display can be made. In addition, the plasma display device including the PDP can be protected from an abnormal temperature rise.
[0019]
[Problems to be solved by the invention]
In the conventional plasma display device as described above, the temperature rise of the PDP is detected using a detector such as a thermocouple, and the plasma display device is protected by the operation of the air cooling device, the warning by the LED, and the power interruption by the relay control device. Yes. However, depending on the video signal to be displayed, only a part of the PDP panel rises in temperature, which may cause thermal stress. When the PDP is deformed by thermal stress, there is an adverse effect such as deterioration of the display performance of the PDP or shortening of the lifetime, and in the worst case, the PDP may be damaged.
[0020]
Since PDP has a certain area, and the main material of PDP is a material with lower thermal conductivity than metals such as glass, the temperature of PDP is not the same at every place of one PDP. Even within a single PDP, the temperature may vary greatly from site to site. For example, when a plasma display device is used as a computer display, a screen that includes a bright window on a relatively dark background often appears. In this window, when only a part of the area is bright and the brightness changes abruptly (such an image is called an image with a large brightness gradient), the bright part is compared to the dark part. More heated. Therefore, if such an image is continuously displayed, a temperature difference between a bright part and a dark part on the PDP widens, and a relatively high temperature part in the PDP expands more than a low part, and thereby, in the PDP. Thermal stress is generated. As the screen size of the PDP is larger, a temperature difference is more likely to occur, which is a big problem particularly in a large-screen display device. Here, in a method using a detector such as a thermocouple as in the conventional plasma display device, a temperature difference in the PDP cannot be detected unless a plurality of detectors are attached to the PDP. In addition, if the screen size of the PDP is increased, more detection points are required and the number of detectors is increased, resulting in an increase in cost.
[0021]
The present invention has been made to solve the above-described problems, and detects an image that causes a large temperature difference in the PDP without using a temperature detection means such as a thermocouple. It is an object of the present invention to obtain a plasma display device and a plasma display panel temperature control method that are low in cost, have little deterioration in image quality, and have a long lifetime by controlling so as to reduce the temperature difference.
[0022]
[Means for Solving the Problems]
A plasma display apparatus according to the present invention includes a driving unit that drives a plasma display panel based on a video signal input from the outside, a plasma display panel that is driven by the driving unit to perform display, and the video signal Sampling means for obtaining a video signal sampled with a smaller number of pixels than the video signal by taking an average value of the number of pixels determined in the vertical direction and the horizontal direction, and a small number of pixels obtained by the sampling means Area dividing means for dividing the video signal into a plurality of areas, and luminance for each of the divided areas A histogram calculation unit for generating a histogram of the image, a determination unit for determining a video with a sharp change in luminance from the histogram generated by the histogram calculation unit, and a control unit for controlling the drive unit based on a determination result of the determination unit It is what has.
[0023]
The number of sustain pulses in the drive means is controlled by the control means.
[0024]
Furthermore, a video signal processing means for processing a video signal inputted from the outside, a driving means for driving a plasma display panel based on the video signal processed by the video signal processing means, and a display driven by the driving means. A plasma display panel to perform, and a video signal processed by the video signal processing means Sampling means for obtaining a video signal sampled with a smaller number of pixels than the video signal by taking an average value of the number of pixels determined in the vertical direction and the horizontal direction, and a small number of pixels obtained by the sampling means Area dividing means for dividing the video signal into a plurality of areas, and luminance for each of the divided areas A histogram calculating unit for generating a histogram of the image, a determination unit for determining a video with a sharp change in luminance from the histogram generated by the histogram calculation unit, and a control for controlling the video signal processing unit based on a determination result of the determination unit Means.
[0025]
In addition, the control means has storage means for holding the control level information for a certain period after the main power is turned off.
[0026]
In addition, a driving unit that drives a plasma display panel based on a video signal input from the outside, a plasma display panel that is driven by the driving unit to perform display, and the video signal Sampling means for obtaining a video signal sampled with a smaller number of pixels than the video signal by taking an average value of the number of pixels determined in the vertical direction and the horizontal direction, and a small number of pixels obtained by the sampling means Area dividing means for dividing the video signal into a plurality of areas, and luminance for each of the divided areas A histogram calculation means for creating a histogram of the image, a determination means for judging a video with a sharp change in luminance from the histogram created by the histogram calculation means, and a communication means for outputting the judgment result of the judgment means to the outside. is there.
[0027]
In addition, panel characteristic storage means for storing the characteristics of the plasma display panel measured in advance is provided, and the determination reference value of the determination means is made variable according to the contents of the panel characteristic storage means.
[0028]
In addition, the image processing apparatus includes coefficient storage means for giving different control coefficients to the control means depending on whether the input video signal is a television signal or a computer signal.
[0029]
Further, the apparatus has temperature detection means for detecting the ambient temperature of the plasma display device, and is configured to correct the determination reference value of the determination means in accordance with the output of the temperature detection means.
[0030]
In addition, the temperature control method of the plasma display panel according to the present invention provides a video signal A sampling step for obtaining a video signal sampled with a smaller number of pixels than the video signal by taking an average value of the number of pixels determined in the vertical direction and the horizontal direction, and a small number of pixels obtained in the sampling step An area dividing step for dividing the video signal into a plurality of areas, and luminance for each of the divided areas A histogram calculation step of creating a histogram of the image, a determination step of determining a video with a sharp change in luminance from the histogram generated by the histogram calculation step, and a control for controlling the luminance of the plasma display panel based on the determination result of the determination step A process.
[0031]
The number of sustain pulses of the plasma display panel is controlled by the control process.
[0032]
The amplitude of the video signal input to the plasma display panel is controlled by the control process.
[0033]
DETAILED DESCRIPTION OF THE INVENTION
In the plasma display apparatus according to the embodiment of the present invention, the video signal By taking the average value of the number of pixels determined in the vertical and horizontal directions, the number of pixels is smaller than that of the video signal. By obtaining a histogram for each luminance of the sampled video signal, the video causing the temperature difference in the PDP is detected and the luminance of the PDP is controlled, so that the temperature difference in the PDP is reduced. .
[0034]
Further, since the brightness of the PDP is controlled by controlling the number of sustain pulses when controlling the brightness of the PDP, the temperature difference in the PDP is reduced by a simple circuit configuration.
[0035]
Further, since the brightness of the PDP is controlled by controlling the video signal processing means, the temperature difference in the PDP can be reduced only by adding a few circuits to the conventional plasma display device having the video signal processing means. Work like so.
[0036]
Further, by holding the control information of the control means in the storage means for a certain period after the main power supply is cut off, even when the main power supply is connected again after a relatively short time, the temperature difference in the PDP is appropriately controlled. Work to reduce.
[0037]
Further, by outputting the determination result of the determination means to the outside by the communication means, the video signal is controlled on the external signal source side, so that the temperature difference in the PDP is not required on the plasma display device side. Work to reduce.
[0038]
Further, by storing the characteristics of the plasma display panel measured in advance in the panel characteristic storage means and making the determination reference value of the determination means variable according to the contents of the panel characteristic storage means, the PDP has a temperature characteristic variation for each panel. Even when there is a variation in temperature characteristics depending on the location within the panel, the temperature difference in the PDP is appropriately reduced according to each temperature characteristic.
[0039]
Also, by changing the control coefficient given to the control means from the coefficient storage means depending on whether the video signal input from the outside is a television signal or a computer signal, the influence on the image quality is minimized by the display according to the signal type It works to reduce the temperature difference in the PDP.
[0040]
In addition, by correcting the judgment value of the control means in accordance with the output of the temperature detection means for detecting the ambient temperature of the plasma display device, the temperature difference in the PDP can be effectively reduced according to the environment where the device is installed and the usage situation. Work to reduce.
[0041]
Hereinafter, the present invention will be specifically described with reference to the drawings showing embodiments thereof.
Embodiment 1 FIG.
First, a first embodiment of the present invention will be described. FIG. 1 is a configuration diagram of a plasma display device according to a first embodiment of the present invention, in which 1 is a drive circuit, 2 is a plasma display panel (PDP), 3 is an average value calculation unit, and 4 is a region. A dividing unit, 5 is a histogram calculation unit, 6 is a determination unit, and 7 is a control unit.
[0042]
Next, the operation will be described. First, the video signal and the synchronization signal are input to the drive circuit 1 and the average value calculation unit 3. The drive circuit 1 stores the input video signal in the frame memory in the drive circuit 1 in the same manner as in the conventional plasma display device, reads it by dividing it into subfields, and outputs it to the X electrode, Y electrode, and address electrode of the PDP 2, respectively. A drive pulse is applied in the same manner as in the conventional plasma display device. The PDP 2 emits light based on the drive pulse given from the drive circuit 1 and displays an image.
[0043]
In the average value calculation unit 3, first, R, G, and B of the color video signal are averaged as pre-processing to obtain a monochrome video signal with only luminance information, and then this monochrome video signal can be determined in the vertical and horizontal directions. By obtaining the average value of the number of pixels, a video signal sampled with a smaller number of pixels than the original video signal is obtained. . Take the average value of the number of pixels determined in the vertical and horizontal directions. This is to remove the influence of the luminance distribution in a relatively small area. For example, when using a PDP as a computer display, there are many opportunities to display characters on the screen. The character includes both high and low luminance pixels in a relatively small area. Thus, even if high-luminance pixels and low-luminance pixels coexist in a relatively small area, it is considered that a large temperature difference that causes a problem does not occur. This is because the heat of the panel is transmitted relatively quickly within a small area, and a large temperature difference does not occur within that range.
[0044]
FIG. 2 is an explanatory diagram showing an example of the operation of the average value calculation unit 3. In this example, the video signal is equivalent to XGA (1024 pixels × 768 pixels). In the figure, (a) represents a video signal of one frame, and an upper left portion of a video composed of 1024 pixels in the horizontal direction and 768 pixels in the vertical direction is shown in an enlarged manner. (b) represents a sampled video signal of one frame after being processed by the average value calculation unit 3, and is composed of 64 pixels in the vertical direction and 48 pixels in the horizontal direction. The average value calculation unit 3 calculates the average of the luminance values over the range of the shaded portion in FIG. 2A, that is, 16 pixels × 16 pixels, and the brightness value of the pixel in the shaded portion at the corresponding position in FIG. And By repeating the above processing over the entire frame, the luminance values of all the pixels in FIG. 2B are obtained.
[0045]
Even if the luminance value distribution is such that high luminance pixels and low luminance pixels are mixed within the range of 16 × 16 pixels by taking the average of luminance values of 16 pixels in the vertical and horizontal directions, it will be described later. The calculation of the luminance distribution can be prevented from being affected. In addition, by using the average value of the luminance values of 256 pixels, the number of pixels of the video signal to be processed is reduced to 1/26 of that of the original image, so that the circuit scale necessary for processing to be described later is reduced. Alternatively, the processing speed can be increased. It should be noted that the number of pixels for which the average value of the luminance values should be determined depends on the total number of pixels of the PDP, the size of the PDP, and the thermal conductivity of the material constituting the PDP.
[0046]
Next, the region dividing unit 4 divides the sampled video signal processed by the average value calculating unit 3 into several regions as shown in FIG. In the example of the figure, a sampled video signal composed of 64 pixels in the horizontal direction and 48 pixels in the vertical direction is divided into 12 regions. By performing the process described later for each of the divided areas, it is possible to know which area in the image the image with the large luminance difference to be detected belongs to, and thus a temperature difference is generated at which position in the PDP. Can be determined by the processing described later.
[0047]
Next, the histogram calculation unit 5 calculates a histogram of luminance values for each of the regions obtained from the region dividing unit 4 by calculation. This will be described with reference to FIGS. FIG. 4 is a diagram showing an example of a region and a histogram corresponding thereto, which is an example without a luminance gradient. FIG. 5 is also a diagram showing an example of a region and a histogram corresponding to the region, and is an example having a large luminance gradient. In each figure, (a) is an example of a region, and (b) is a histogram obtained from (a). Here, for simplicity, the luminance value is divided into three ranges of low luminance, medium luminance, and high luminance. In FIG. 4A and FIG. 5A, the pixels represented by black have low luminance, the pixels represented by diagonal lines have medium luminance, and the pixels represented by white have high luminance. When the respective histograms are formed, they are as shown in FIGS. 4B and 5B. Actually, the histogram is created by dividing the luminance value into a larger range. For example, when the luminance value is divided into 8 and the luminance is 256 gradations (0 to 255), 0 to 31, 32 to 63, 64 to 95, 96 to 127, 128 to 159, 160 to 191, 192 to 223, The luminance values may be divided into eight equal parts like 224 to 255, and the number of pixels in the range of each luminance value may be formed into a histogram.
[0048]
Next, the determination unit 6 determines whether or not there is a large luminance gradient based on the histogram data obtained from the histogram calculation unit 5 by a method described later. Since there is one histogram for each divided area, the determination is first made for the histogram for each area, and then the values of the luminance ranges of the histograms of the two adjacent areas are added together to obtain two histograms. Histograms are synthesized, and the synthesized histogram is also determined by the method described later. By synthesizing the histograms of two adjacent regions in this way, it is possible to detect a luminance gradient that extends over the two adjacent regions. Furthermore, the histogram of the entire video signal of one frame can be obtained by adding together the values of the respective luminance ranges for all the histograms for one frame. The determination for the entire histogram of one frame can be performed more reliably by performing the determination by the method described later.
[0049]
Next, specific determination criteria will be described. In an image with a large luminance gradient, both high luminance pixels and low luminance pixels exist in one histogram, and the number of intermediate luminance pixels is small. Therefore, it is determined that there is a large luminance gradient when the ratio of the number of intermediate luminance pixels to all the pixels is smaller than a certain value and the number of high luminance pixels is larger than a certain value.
[0050]
When the above determination is performed on each of the histogram of each region, the histogram obtained by combining the histograms of adjacent regions, and the histogram of the entire screen as described above, when at least one histogram is determined to have a large luminance gradient In addition, the determination unit 6 outputs a signal indicating “with luminance gradient” to the control unit 7, and when it is determined that there is no large luminance gradient in all histogram determinations, the signal indicating “no luminance gradient” to the control unit 7. Is output.
[0051]
Finally, the control unit 7 controls the drive circuit 1 based on the determination result obtained by the determination unit 6 to control the drive circuit 1 to reduce the number of sustain pulses in each subframe, thereby reducing the display luminance of the PDP 2. By reducing the value, the occurrence of a temperature difference in the panel can be suppressed. Since the brightness is proportional to the number of pulses, when it is desired to set the brightness to x% with the brightness in the standard state (state without brightness control) being 100%, in the standard state (state without brightness control) If Ps is the number of pulses and Pc is the number of pulses when the control is performed, Pc = Ps × x / 100 may be set. Actually, since the number of pulses is an integer, the control is performed in stages. A large temperature difference is generated in the PDP when a video signal having a luminance gradient is continuously displayed for a certain period. Therefore, the actual control depends on whether or not there is a luminance gradient in a past period. It needs to be done in a dependent manner. A specific control method will be described with reference to FIG.
[0052]
FIG. 6 is a flowchart showing the operation of the control unit in Embodiment 1 of the present invention. S001 is an initial setting, and is executed only once when the plasma display apparatus is powered on. Here, W_CNT and NW_CNT are variables whose values are held inside the control unit 7, respectively, and take integer values. Each variable includes information on the luminance gradient in the past frame. In S001, the variable W_CNT and the variable NW_CNT are initialized. As the initial values, 0 is given to the variable W_CNT, and a certain integer WMAX is given to the variable NW_CNT.
[0053]
In subsequent S002, a determination result for one frame regarding the presence or absence of a luminance gradient is acquired from the determination unit 6. In B001, depending on the determination result acquired in S002, the process branches to either S003 if there is a luminance gradient, or S007 if there is no luminance gradient.
[0054]
First, a case where there is a luminance gradient, that is, a case where the process branches to S003 will be described. In S003, both the variable W_CNT and the variable NW_CNT are incremented by one. In the next B002 and S004, when the variable NW_CNT is equal to or greater than WMAX, WMAX is substituted into the variable NW_CNT. In B003, when the variable W_CNT is greater than or equal to WMAX, the process proceeds to S005, and 0 is substituted into the variable W_CNT, and then the drive circuit 1 is controlled in S006 to control the brightness of the PDP2. In S006, the brightness control value is decreased by one step. That is, the number of sustain pulses in the drive circuit 1 is reduced by one stage set in advance. As a result, nothing is done when the control value falls below a preset lower limit value. When the above processing is completed, the process returns to S002 and waits until the determination result of the next frame is acquired.
[0055]
Next, a case where there is no luminance gradient, that is, a case where the process branches to S007 will be described. In S007, both the variable W_CNT and the variable NW_CNT are decreased by one. In the next B004 and S008, 0 is substituted into the variable W_CNT when the variable W_CNT is 0 or less. In B005, when the variable NW_CNT becomes 0 or less, the process proceeds to S009, WMAX is substituted into the variable NW_CNT, and then the brightness of the PDP 2 is controlled by controlling the drive circuit 1 in S010. In S010, the brightness control value is increased by one step. As a result, when the control value exceeds the upper limit value (number of pulses in the standard state), nothing is done. When the above processing is completed, the process returns to S002 and waits until the determination result of the next frame is acquired.
[0056]
Control is performed by repeating the above processing every frame. This control method will be described with reference to FIG. FIG. 7 is a diagram showing an example of the operation of the control unit according to the first embodiment of the present invention, and is a graph showing the control status of the variable W_CNT, the variable NW_CNT, and the control value (the standard state is 0 stage). . The horizontal axis represents time in number of frames. In the example of the figure, after a state with a luminance gradient continues for 25 frames, it changes without a luminance gradient. As can be seen from the figure, the control is performed so that the control value is lowered by one step when the situation with the luminance gradient continues during the WMAX frame. Control is performed for each WMAX frame even in the fastest case, and correct control is performed without being affected even if the video changes at high speed during several frames. In the graph of FIG. 7, WMAX = 10 is set for simplicity, but in practice, it is desirable that the luminance change is about once every several seconds to prevent flicker, and WMAX is about several hundreds.
[0057]
By performing the control as described above, when an image having a luminance gradient that causes a temperature difference is displayed in the PDP, the luminance is gradually reduced and an image having no luminance gradient is displayed. In some cases, the luminance is increased in steps (returned to the standard state), and a large temperature difference can be prevented from occurring in the PDP.
[0058]
Embodiment 2. FIG.
Next, a second embodiment of the present invention will be described. In the first embodiment, in order to control the display brightness of the PDP 2, the drive circuit 1 is controlled by the control unit 7 to reduce the number of sustain pulses. However, instead of controlling the drive circuit 1, the display contrast is increased by signal processing. It can also be lowered. In the plasma display device of the first embodiment, only a digital video signal is assumed as an input. However, in the conventional plasma display device, various inputs are assumed, for example, a video signal is decoded. Many of them include signal processing circuits having functions such as converting analog video signals into digital video signals by A / D conversion, performing inverse gamma conversion, brightness adjustment, and contrast adjustment. Therefore, by controlling the contrast adjustment function in such a signal processing circuit, the contrast is lowered when an image that causes a large temperature difference is detected. Such an embodiment will be described below. FIG. 8 is a block diagram of the plasma display device according to the second embodiment of the present invention. Reference numerals 1 to 7 are the same as those in the first embodiment, and 8 is a video signal processing circuit for controlling the contrast of the video signal. It includes the function to do.
[0059]
The operation of the plasma display device configured as described above will be described. The operations of the drive circuit 1, the PDP 2, the average value calculation unit 3, the region division unit 4, the histogram calculation unit 5, and the determination unit 6 are the same as those in the first embodiment. The control unit 7 controls the brightness of the PDP 2 by controlling the contrast adjustment function in the video signal processing circuit 8 based on the determination result of the determination unit 6 and adjusting the contrast. Contrast adjustment is performed by setting the result of multiplying the brightness value before adjustment by the contrast value as the brightness value after adjustment. Therefore, when it is desired to set the brightness to x% with the brightness in the standard state (state where brightness control is not performed) being 100%, the contrast value may be Cc = x / 100.
[0060]
The control procedure is performed by controlling the contrast stepwise in accordance with, for example, the flowchart of FIG. 6 as in the first embodiment. As a result, when an image with a brightness gradient that causes a temperature difference is displayed in the PDP, the brightness is lowered stepwise, and when an image without a brightness gradient is displayed, the brightness is stepped. Therefore, it is possible to prevent a large temperature difference from being generated in the PDP.
[0061]
Embodiment 3 FIG.
Next, a third embodiment of the present invention will be described. In the plasma display device, when the main power supply is turned off, it takes a certain amount of time for the PDP to cool to a temperature close to room temperature. For this reason, when the user turns off the main power supply to interrupt the use of the plasma display device, the main power supply is connected again after a relatively short time, and the use is resumed. If this happens, a temperature gradient may remain in the PDP. In the third embodiment, even when the main power supply is temporarily cut off as described above, the brightness control is appropriately performed to prevent the temperature difference in the PDP. FIG. 9 is a block diagram of a plasma display device according to Embodiment 3 of the present invention. In the figure, 1 to 7 are the same as those in Embodiment 1, and 9 is for storing the control state of the control unit 7. For example, a RAM. Reference numeral 10 denotes a backup circuit for holding the contents of the storage device 9 for a certain period regardless of the main power source.
[0062]
The storage device 9 stores, for example, the current luminance control value as a control state of the control unit 7, and also stores a check pattern for determining whether the stored content is valid.
[0063]
The backup circuit 10 supplies power for the storage device 9 to retain stored contents from when the main power supply is turned off. An example of the circuit of the backup circuit 10 is shown in FIG. In the figure, a circuit surrounded by a broken line corresponds to the backup circuit 10, 20 is a diode, and 21 is a capacitor. When the main power supply is connected, a current flows through the diode 20 and charges are accumulated in the capacitor 21. When the main power supply is cut off, a current flows through the storage device 9 until the electric charge is discharged from the capacitor 21. When the capacitor 21 is completely discharged while the main power supply is cut off, no power is supplied to the storage device 9, and the stored contents are erased. The approximate time Tm from when the main power is turned off until the stored contents are erased is determined by the capacity of the capacitor 21. It is assumed that the capacitance of the capacitor 21 is selected so that the time Tm is longer than the time Tp required for the PDP panel to be naturally cooled to approximately the same as room temperature after the main power supply is turned off.
[0064]
An operation of the control unit 7 configured as described above will be described. When the main power is turned on, the control unit 7 reads the check pattern storage location in the storage device 9 and determines whether or not a prescribed check pattern is stored. If the check pattern is not stored, a sufficient time has passed since the previous main power-off, and the PDP has been cooled to the same temperature as the room temperature. Initialization is performed, a check pattern is written, and a control value is set to a specified initial value. When the check pattern is stored, since the PDP has not been cooled for a short time since the main power supply was cut off last time, the brightness control value in the storage device 9 is read and used as the control value. After the above operation is performed when the main power is turned on, the normal operation is started. During normal operation, the control unit 7 stores the updated control value in the storage device 9 every time the control value is updated. Other operations of the control unit 7 are the same as those in the first embodiment.
[0065]
In the plasma display device configured as described above, even when the main power supply is connected again in a relatively short time after the main power supply is turned off, control is performed using the held control value. It is possible to prevent the difference from occurring. In addition, even when a long time has passed since the main power supply was cut off and the PDP is at a temperature approximately equal to room temperature, the stored control value can be discarded and the control can be appropriately performed from the initial value. .
[0066]
Embodiment 4 FIG.
Next, a fourth embodiment of the present invention will be described. In the fourth embodiment, unlike the first to third embodiments, the luminance control is performed outside the plasma display device, thereby reducing the cost of the device. Many of the images that cause a large temperature difference are generated when a plasma display device is used as a computer display. Therefore, the plasma display device determines an image that causes a temperature difference and outputs the determination result as a video signal. The computer can transmit the image data to the computer side and perform processing on the computer side to perform brightness control. FIG. 11 is a block diagram of the plasma display device according to the fourth embodiment of the present invention. In the figure, 1 to 6 are the same as those of the first embodiment, and 11 is a determination result of the determination unit 6 transmitted to the outside. A communication unit 12 is provided outside the plasma display device of the present embodiment, supplies a video signal to the plasma display device, and receives a determination result from the communication unit 11 to perform processing. And signal sources such as workstations.
[0067]
The operation of the plasma display device configured as described above will be described. The operations of the drive circuit 1, the PDP 2, the average value calculation unit 3, the region division unit 4, and the histogram calculation unit 5 are the same as those in the first embodiment. The determination unit 6 determines whether or not there is a luminance gradient for each of the histogram of each region, the histogram obtained by combining the histograms of adjacent regions, and the histogram of the entire screen, as in the embodiment, and returns to the communication unit 11. The determination result is sent out including the position information of the area where the luminance gradient is present. The communication unit 11 sends the information received from the determination unit 6 to the external signal source 12. Processing is performed on the side of the external signal source 12, and based on the information received from the communication unit 11, the display state is changed so that the luminance of the window display portion corresponding to the position where the luminance gradient exists is lowered. For example, by changing the display color of the window part, it is possible to control the luminance so as to prevent the occurrence of a temperature difference without changing the part other than the corresponding window.
[0068]
Embodiment 5 FIG.
Next, a fifth embodiment of the present invention will be described. The temperature characteristics of the PDP may vary from panel to panel due to manufacturing variations, and there may be variations in temperature characteristics depending on the location of a single PDP. The fifth embodiment is configured so that appropriate luminance control can be performed even when there is such a variation. 12 is a block diagram of a plasma display device according to a fifth embodiment of the present invention. In the figure, reference numerals 1 to 7 are the same as those in the embodiment, and reference numeral 13 is a PDP characteristic storage for storing determination criteria in the determination unit 6. A non-volatile memory such as a PROM.
[0069]
In the plasma display device configured as described above, for example, the temperature characteristic of the PDP 2 is measured at the time of manufacturing the plasma display apparatus, and the determination reference for determining the presence or absence of the luminance gradient based on the result is used as the PDP characteristic storage unit 13. To store. When the plasma display apparatus is used, the determination unit 6 determines the presence or absence of a luminance gradient using the determination reference read from the PDP characteristic storage unit 13, thereby manufacturing variations in each panel of the PDP 2 and each part of the panel. Since the determination can be corrected in accordance with the variation in the characteristics, brightness control can be performed more appropriately.
[0070]
Hereinafter, an example of a method for measuring the temperature characteristics of the PDP 2 at the time of manufacturing the plasma display device will be described. In measurement, a signal including a test pattern is used as a test signal. As the test pattern, for example, a graphic having a certain size such as a square, the luminance value of the graphic portion being maximized and the luminance value of the other background portion being 0 is used. By performing measurement while changing the display position and area of such a test pattern, it is possible to measure the difference in characteristics depending on the display part of the PDP 2. FIG. 13 is a diagram for explaining the display position of the test pattern, and L1 to L12 represent the display position of the test pattern. Here, each display position corresponds to an area in the area dividing unit 4, and when a test pattern is displayed at positions L1 to L12, the display of the pattern can be detected by the histogram distribution of the corresponding area. it can.
[0071]
A specific measurement procedure will be described. First, a video signal that causes the PDP 2 to display all black is input from the drive circuit 1, and the temperature distribution on the PDP 2 is actually measured using a thermocouple or the like to confirm that there is no temperature difference in the PDP 2. To do. Thereafter, a video signal for displaying a test pattern having a reference area A0 at the display position L1 is input from the drive circuit 1 and displayed on the PDP 2 for a unit time. By actually measuring the temperature distribution on the PDP 2 using a thermocouple or the like, the in-plane maximum temperature difference T1 is obtained.
[0072]
Next, a video signal that causes the PDP 2 to display all black again is input from the drive circuit 1, and after a sufficient time has passed until the temperature difference in the PDP 2 disappears, a test pattern having an area A0 at the position L2 is created. A video signal to be displayed is input from the drive circuit 1 and displayed on the PDP 2 for a unit time. By actually measuring the temperature distribution on the PDP 2 using a thermocouple or the like, the in-plane maximum temperature difference T2 at the display position L2 is obtained. Similarly, the test pattern display positions are measured as L3, L4,..., L12, and the in-plane maximum temperature differences T3, T4,.
[0073]
The determination criteria are determined as follows. The temperature difference T1 measured as described above is compared with a predetermined reference value T0. When T1 = T0, a determination criterion in an area corresponding to L1 is determined so that it is determined that there is a luminance gradient when a pattern having an area of A0 or more is displayed, and the determination criterion is determined according to the difference between T1 and T0. Change. That is, when T1> T0, the criterion is made strict so that a pattern having an area smaller than A0 is determined to have a luminance gradient. On the other hand, when T1 <T0, the determination criterion is relaxed so that a pattern having a slightly larger area than A0 is determined to have no luminance gradient. Similarly, by comparing T2, T3,..., T12 with T0, the determination criterion for the region corresponding to L2, L3,... L12 is determined, and the determination criterion for each region is stored in the PDP characteristic storage unit 13. . By the method as described above, the determination criteria corresponding to each region can be stored in the PDP characteristic storage unit 13.
[0074]
Next, an operation when the plasma display apparatus is used will be described. When the determination unit 6 determines the presence / absence of a luminance gradient, the determination reference corresponding to the region of the histogram to be determined is read from the PDP characteristic storage unit 13, and determination is performed based on this. When making a determination in a histogram that combines the histograms of adjacent regions, the determination is made based on both of the determination criteria corresponding to the two regions, and if any one of the luminance gradients is determined to have a luminance Has a gradient. Also, in a histogram obtained by combining all histograms for one frame, it is determined that there is a luminance gradient when it is determined that there is a luminance gradient according to any one of the determination criteria. Other operations are the same as those in the first embodiment.
[0075]
In the plasma display device configured as described above, measurement was performed in advance even when there was a variation in temperature characteristics of each panel in the PDP or when there was a variation in temperature characteristics depending on the part in the panel. Since the presence / absence of a luminance gradient is determined based on a determination criterion corresponding to the temperature characteristic, and temperature control is performed based on the determination, a temperature difference in the plasma display panel can be prevented.
[0076]
Embodiment 6 FIG.
Next, a sixth embodiment of the present invention will be described. When the plasma display device is used as a display for a computer, for example, the window is often continuously displayed at the same position. However, when the plasma display device is used as a display for a television, the entire image often changes greatly with time. As described above, since there is a difference in the tendency of the video signal depending on the application of the display, in this embodiment, the control method is changed so as to perform luminance control suitable for each. FIG. 14 is a block diagram of a plasma display device according to a sixth embodiment of the present invention. In the figure, reference numerals 1 to 7 are the same as those in the first embodiment, and reference numeral 14 denotes a TV signal input from the outside. This is a control coefficient storage unit that gives a control coefficient to the control unit 7 based on an identification signal that distinguishes whether it is a computer signal or not.
[0077]
FIG. 15 is a diagram illustrating the configuration of the control coefficient storage unit 14 according to the sixth embodiment. In the figure, reference numeral 22 denotes a TV signal time control coefficient storage in which a control coefficient when the input signal is a television signal is stored in advance. , 23 is a PC signal time control coefficient storage unit that stores in advance a control coefficient when the input signal is a computer signal, and 24 is a TV signal time control coefficient storage unit 22 and a PC signal time control coefficient storage based on the identification signal. This is a switch for switching the output of the unit 23 and giving it to the control unit 7.
[0078]
In the sixth embodiment configured as described above, the switch 24 is switched depending on whether the input signal is a television signal or a computer signal, and when the input signal is a TV signal, the control unit 7, the control coefficient is given from the TV signal time control coefficient storage unit 22, and when the input signal is a PC signal, the control coefficient is given to the control unit 7 from the PC signal time control coefficient storage unit 23. That is, it is possible to change the speed and magnitude of the control operation of the control unit 7 by changing the control coefficient according to the input signal.
[0079]
As a specific control coefficient, for example, WMAX shown in FIGS. 6 and 7 can be cited. Hereinafter, a case where WMAX is used as a control coefficient will be described. In this case, WMAX_TV is stored in the TV signal time control coefficient unit 22, and WMAX_PC is stored in the PC signal time control coefficient unit 23. As a result, WMAX in the control unit 7 uses either WMAX_TV or WMAX_PC according to the input signal.
[0080]
In the control unit 7, when the value of WMAX is large, the number of frames from when the luminance gradient is detected to when the luminance control is actually performed increases, so that the luminance changes slowly. Conversely, when WMAX is small, the number of frames from when the luminance gradient is detected until luminance control is performed decreases, and the luminance changes quickly.
[0081]
On the other hand, if the input signal is a television signal, darkening the image due to brightness control leads to a decrease in image quality, so it is desirable to perform the control gently. Since it is considered that a temperature difference is likely to occur, it is necessary to shorten the time from when the luminance gradient is detected until the luminance control is performed. In order to realize such a demand, WMAX_TV may be set to a larger value than WMAX_PC.
[0082]
By storing WMAX_TV and WMAX_PC in the TV signal time control coefficient unit 22 and the PC signal time control coefficient unit 23 as described above, the speed at which the control is performed varies depending on the type of the input signal, and both the TV signal and the computer signal are stored. Assuming that the input signal is input, it is possible to effectively prevent the temperature difference in the plasma display panel while minimizing the deterioration of the image quality of the TV signal.
[0083]
In the above example, WMAX is used as the control coefficient. In addition, for example, the width of the actual luminance change when the control value is changed in one step is used as the control coefficient. The same effect can be obtained by reducing the luminance change per control and increasing it in the case of a PC signal.
[0084]
Embodiment 7 FIG.
Next, a seventh embodiment of the present invention will be described. If the atmospheric temperature in the plasma display device becomes high due to continuous use of the plasma display device or the influence of room temperature, there is a possibility that the temperature change of the PDP will be greatly affected. In the eighth embodiment, the temperature difference in the plasma display panel is more effectively detected by detecting the ambient temperature in the plasma display device by a temperature detecting means such as a thermocouple and correcting the control method of the control unit based on the detection result. It is configured to prevent this. FIG. 16 is a configuration diagram of a plasma display device according to the seventh embodiment of the present invention. In the figure, 1 to 7 are the same as those in the first embodiment, 15 is a temperature detector such as a thermocouple, The atmospheric temperature of the plasma display device is detected and a detection result is given to the control unit 7.
[0085]
In the plasma display device configured as described above, the control method is corrected according to the atmospheric temperature detected by the temperature detector 15. In other words, when the ambient temperature is high, the brightness can be quickly increased by shortening the time from the detection of the brightness gradient until the brightness control is performed, or by correcting so as to increase the width of the brightness control in one stage. Control to lower. Conversely, when the ambient temperature is low, unnecessary deterioration in image quality can be suppressed by performing correction so that the control is performed gently. By performing the control as described above, a temperature difference in the display panel can be more effectively prevented. Since at least one temperature detector 15 for measuring the ambient temperature is sufficient, the increase in manufacturing cost is small.
[0086]
【The invention's effect】
Since the present invention is configured as described above, the following effects can be obtained.
[0087]
By creating a histogram of the video signal, it is determined whether or not there is a large luminance gradient in the video signal, and the luminance is controlled. Therefore, the temperature difference in the PDP can be obtained without using temperature detection means such as a thermocouple. Therefore, it is effective in reducing the cost of the plasma display device, preventing the deterioration of display quality, and extending the service life.
[0088]
In addition, since the brightness of the PDP is controlled by controlling the number of sustain pulses when controlling the brightness of the PDP, the temperature difference in the PDP can be reduced with a simple circuit configuration. This is effective in improving the display quality, preventing the deterioration of display quality, and extending the service life.
[0089]
Further, since the brightness of the PDP is controlled by controlling the amplitude of the video signal, the temperature difference in the PDP can be reduced only by adding a few circuits to the conventional plasma display device having the video signal processing means. Therefore, the cost of the plasma display device can be reduced, display quality can be prevented from being deteriorated, and the life can be extended.
[0090]
Further, by holding the control information of the control means in the storage means for a certain period after the main power supply is cut off, even when the main power supply is connected again after a relatively short time, the temperature difference in the PDP is appropriately controlled. Therefore, it is effective in reducing the cost of the plasma display device, preventing the deterioration of display quality, and extending the life.
[0091]
Further, by outputting the determination result of the determination means to the outside by the communication means, the video signal is controlled on the external signal source side, so that the temperature difference in the PDP is not required on the plasma display device side. Therefore, it is effective in reducing the cost of the plasma display device, preventing the deterioration of display quality, and extending the life.
[0092]
Further, by storing the characteristics of the plasma display panel measured in advance in the panel characteristic storage means and making the determination reference value of the determination means variable according to the contents of the panel characteristic storage means, the PDP has a temperature characteristic variation for each panel. Even if there is a variation in temperature characteristics depending on the location within the panel, the temperature difference in the PDP can be reduced appropriately according to each temperature characteristic, thereby reducing the cost of the plasma display device Effective in preventing deterioration of display quality and extending life.
[0093]
Also, by changing the control coefficient given to the control means from the coefficient storage means depending on whether the video signal input from the outside is a television signal or a computer signal, the influence on the image quality is minimized by the display according to the signal type Since the temperature difference in the PDP can be reduced to the limit, it is effective in reducing the cost of the plasma display device, preventing the deterioration of display quality, and extending the life.
[0094]
In addition, by correcting the control coefficient of the control means in accordance with the output of the temperature detection means for detecting the ambient temperature of the plasma display device, the temperature difference in the PDP can be effectively reduced according to the environment where the device is installed and the usage situation. Therefore, the plasma display device can be reduced in cost, display quality can be prevented from being deteriorated, and the life can be extended.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a plasma display device according to a first embodiment of the present invention.
FIG. 2 is an explanatory diagram showing an operation of an average value calculation unit according to Embodiment 1 of the present invention.
FIG. 3 is an explanatory diagram showing an operation of an area dividing unit according to Embodiment 1 of the present invention.
FIG. 4 is a diagram showing an example of histogram calculation when there is no luminance gradient in Embodiment 1 of the present invention.
FIG. 5 is a diagram showing an example of histogram calculation when there is a luminance gradient in Embodiment 1 of the present invention.
FIG. 6 is a flowchart showing an operation of a control unit in the first embodiment of the present invention.
FIG. 7 is a diagram showing an example of an operation of a control unit in the first embodiment of the present invention.
FIG. 8 is a configuration diagram of a plasma display device according to a second embodiment of the present invention.
FIG. 9 is a configuration diagram of a plasma display device according to a third embodiment of the present invention.
FIG. 10 is a diagram showing an example of a backup circuit according to Embodiment 3 of the present invention.
FIG. 11 is a configuration diagram of a plasma display device according to a fourth embodiment of the present invention.
FIG. 12 is a configuration diagram of a plasma display device according to a fifth embodiment of the present invention.
FIG. 13 is a diagram showing a display position of a test signal in Embodiment 5 of the present invention.
FIG. 14 is a configuration diagram of a plasma display device according to a sixth embodiment of the present invention.
FIG. 15 is a diagram showing a configuration of a control coefficient storage unit in Embodiment 6 of the present invention.
FIG. 16 is a block diagram of a plasma display device according to a seventh embodiment of the present invention.
FIG. 17 is a block diagram showing a conventional plasma display device.
FIG. 18 is a timing chart showing the operation of a conventional plasma display device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Drive circuit, 2 Plasma display panel, 3 Average value calculation part, 4 Area division part, 5 Histogram calculation part, 6 Determination part, 7 Control part, 8 Video signal processing circuit, 9 Storage device, 10 Backup circuit, 11 Communication part , 13 PDP characteristic storage unit, 14 control coefficient storage unit, 15 temperature detector.

Claims (11)

Driving means for driving a plasma display panel based on a video signal input from the outside, a plasma display panel driven by the driving means for display, and an average of the number of pixels determined in the vertical and horizontal directions of the video signal Sampling means for obtaining a video signal sampled with a smaller number of pixels than the video signal, and area dividing means for dividing the video signal with a smaller number of pixels obtained by the sampling means into a plurality of areas by taking a value; A histogram calculating unit that creates a luminance histogram for each of the divided areas , a determination unit that determines an image with a sharp luminance change from the histogram generated by the histogram calculation unit, and a determination result of the determination unit, Control means for controlling the driving means. Plasma display device.   2. The plasma display apparatus according to claim 1, wherein the number of sustain pulses in the driving means is controlled by the control means. Video signal processing means for processing an externally input video signal, driving means for driving a plasma display panel based on the video signal processed by the video signal processing means, and a plasma display driven by the driving means for display By taking an average value of the number of pixels determined in the vertical direction and the horizontal direction of the video signal processed by the panel and the video signal processing means, a video signal sampled with a smaller number of pixels than the video signal is obtained. Sampling means, area dividing means for dividing a video signal with a small number of pixels obtained by the sampling means into a plurality of areas, histogram calculating means for creating a luminance histogram for each of the divided areas, and the histogram calculation Images with sharp changes in brightness from histograms created by the means A determination unit, wherein based on the determination result of the determination unit, a plasma display apparatus characterized by a control means for controlling said video signal processing means.   4. The plasma display apparatus according to claim 1, further comprising storage means for holding the control level information of the control means for a certain period after the main power supply is turned off. Driving means for driving a plasma display panel based on a video signal input from the outside, a plasma display panel driven by the driving means for display, and an average of the number of pixels determined in the vertical and horizontal directions of the video signal Sampling means for obtaining a video signal sampled with a smaller number of pixels than the video signal, and area dividing means for dividing the video signal with a smaller number of pixels obtained by the sampling means into a plurality of areas by taking a value; A histogram calculation unit that creates a luminance histogram for each of the divided areas , a determination unit that determines a video with a sharp change in luminance from the histogram generated by the histogram calculation unit, and a determination result of the determination unit to the outside A plasma display having a communication means for outputting B devices.   A panel characteristic storage means for storing characteristics of the plasma display panel measured in advance is provided, and a determination reference value of the determination means is variable according to the contents of the panel characteristic storage means. Item 6. The plasma display device according to any one of Items 5 to 6.   7. The plasma according to claim 1, further comprising coefficient storage means for giving a different control coefficient to the control means depending on whether the input video signal is a television signal or a computer signal. Display device.   The temperature detection means for detecting the atmospheric temperature of the plasma display device is provided, and the determination reference value of the determination means is corrected in accordance with the output of the temperature detection means. 2. The plasma display device according to 1. A sampling step for obtaining a video signal sampled with a smaller number of pixels than the video signal by taking an average value of the number of pixels determined in the vertical direction and the horizontal direction of the video signal, and a pixel obtained in the sampling step A region dividing step for dividing a small number of video signals into a plurality of regions, a histogram calculating step for creating a luminance histogram for each of the divided regions, and a video with a sharp change in luminance from the histogram created by the histogram calculating step And a control step of controlling the brightness of the plasma display panel based on the determination result of the determination step.   10. The temperature control method of a plasma display panel according to claim 9, wherein the number of sustain pulses of the plasma display panel is controlled by the control step.   10. The temperature control method for a plasma display panel according to claim 9, wherein the amplitude of a video signal input to the plasma display panel is controlled by the control step.

Images