JP4310075B2 - Plasma display device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a plasma display apparatus that displays a single screen by combining a plurality of subfields including a reset period, an address period, and a sustain period, and particularly changes the luminance in the screen in accordance with the intensity of ambient light. The present invention relates to a plasma display device.
[0002]
[Prior art]
Conventionally, this type of plasma display apparatus is disclosed in Japanese Patent Laid-Open No. 10-207426, and will be described below with reference to FIGS. FIG. 5 is an overall block diagram of a conventional plasma display device, and FIGS. 6 to 8 are field configuration diagrams of the conventional plasma display device.
[0003]
Referring to FIG. 5, the conventional plasma display apparatus includes a plasma display panel 101, an address electrode driving circuit 102 for controlling driving of address electrodes, a Y electrode driving circuit 104 for controlling driving of Y electrodes, and driving of X electrodes. An X electrode driving circuit 103 for controlling, a frame memory 106 to which an image signal is inputted, a memory writing control circuit 107 for controlling writing in the frame memory 106, and a memory reading control circuit 108 for controlling reading of the frame memory 106; A drive pulse generation circuit 109 for generating various drive pulses to be supplied to the address electrodes, the X electrodes, and the Y electrodes, an ambient light detection circuit 105 that mainly includes an optical sensor circuit and detects ambient brightness, and each subfield. A control signal for increasing or decreasing at the same ratio is a drive pulse generating circuit 1 9, the number of subfield sustain discharge times control circuit 110 supplied to 9, the field rest period detection circuit 111 for detecting the sum of rest periods after the sustain discharge period of each subfield, and the position of the total rest period in one field It is a structure provided with the idle period rearrangement control circuit 112 which allocates what to do.
[0004]
In the driving operation of the conventional plasma display device, as shown in FIG. 6, one field (also referred to as one frame) is divided into a plurality of subfields (subframes) to perform halftone display of the image signal. In a driving operation in which a field is constituted by a reset period, an address period, and a sustain discharge period, and is driven so as to perform a sustain discharge as many times as necessary for halftone display of the image signal in the sustain discharge period, the ambient light detection circuit 105 Detects the brightness around the plasma display panel 101, and the subfield sustain discharge frequency control circuit 110 increases or decreases the sustain discharge period length in each subfield in one field at the same ratio according to the detection result. (See FIG. 7), and occurs when the sustain discharge period length of each subfield is reduced. The field pause period detection circuit 111 detects the total pause period as the total pause period, and the pause period rearrangement control circuit 112 indicates the pause period in one field as shown in FIG. The configuration was rearranged.
[0005]
Thus, if the total discharge period is rearranged by increasing / decreasing the sustain discharge period length in each subfield at the same ratio in each subfield, the display period and the rest period are separated within one field period. Therefore, as the brightness around the plasma display panel 101 becomes darker, the display period within one field period can be shortened. When adjusting the brightness of the plasma display device, the number of display gradations and the display bits are reduced. The change in the number of sustain discharges can be switched without impairing the accuracy, and the contrast can be made constant.
[0006]
[Problems to be solved by the invention]
If the number of sustain discharges is reduced too much in accordance with the decrease in the brightness around the plasma display device, the ratio of the rest period to one field increases and flicker occurs. Therefore, the brightness of the image is displayed when the plasma display panel 101 is displayed normally. The adjustment range is small. In addition, when the ambient brightness is extremely small, the background luminance does not decrease even if the sustain discharge period length of each subfield is decreased at the same ratio, so that there is a problem that improvement in contrast cannot be expected.
[0007]
The present invention has been made in order to solve the above-described problems. The present invention has been made to increase the adjustment range of the brightness of an image displayed on the plasma display panel while maintaining the display quality of the plasma display panel. An object of the present invention is to provide a plasma display device in which the brightness of a plasma display panel is adjusted to maintain a constant contrast and the contrast is further improved.
[0008]
[Means for Solving the Problems]
The plasma display device according to the present invention is a plasma display panel in which a first substrate on which a main electrode is disposed and a second substrate on which an address electrode is disposed are arranged to face each other via a discharge space. With , The plasma display panel In Halftone display by multiple subfields consisting of reset period, address period, and sustain period Make In the plasma display device, a light detection unit for detecting the intensity of ambient light of the plasma display panel; Of the light detector Based on the detection result light intensity Before Record Displayed on the plasma display panel Display surface A peak luminance adjustment circuit capable of adjusting the peak luminance and the display surface; Adjustable background brightness Provided with background brightness adjustment circuit With brightness adjustment section The peak luminance adjustment circuit relatively increases the number of sustain pulses in the sustain period when the intensity of the light detected by the light detection unit is relatively large, while the light provided from the light detection unit. When the intensity of the light is relatively small, the number of sustain pulses in the sustain period is relatively decreased, and the background luminance adjustment circuit has a relatively high intensity of light detected by the light detection unit. If it is small, the voltage level of the reset pulse in the reset period is relatively lowered. The As described above, in the present invention, since the luminance adjustment unit adjusts the background luminance based on the intensity of ambient light detected by the light detection unit, the contrast determined by the peak luminance and the background luminance is more than a certain level under any environment. Can keep.
[0009]
Ma Book In the invention, since the brightness adjusting unit changes at least one of the pulse shape, the number of subfields, and the number of sustain pulses according to the intensity of ambient light detected by the light detection unit, the peak is set according to the ambient light. The brightness and / or background brightness can be changed, and the contrast can be surely kept above a certain level.
[0010]
Ma Book In the invention, as the ambient light becomes smaller, the brightness adjusting unit Background brightness adjustment circuit Since the background brightness is reduced, when a dark part is displayed on the panel in a dark room, display can be performed with appropriate brightness that is not too bright, and a certain level of contrast can be maintained.
[0011]
Ma Book In the present invention, the brightness adjusting unit is reduced as the ambient light intensity decreases. Peak brightness adjustment circuit Since the peak luminance is reduced, when a bright part is displayed on the panel in a dark room, it is possible to display with an appropriate luminance that is not too bright.
[0012]
Ma Book In the present invention, the brightness adjusting unit is reduced as the ambient light intensity decreases. Background brightness adjustment circuit However, since the voltage level of the reset pulse is lowered, the background luminance can be reduced.
[0013]
Ma Book In the present invention, the brightness adjusting unit is reduced as the ambient light intensity decreases. Peak brightness adjustment circuit However, since the number of sustain pulses in the sustain period is reduced, the peak luminance can be reduced without reducing the number of gradations.
[0014]
The plasma display device according to the present invention is When the intensity of light detected by the light detection unit is relatively small, the peak luminance adjustment circuit further increases the address width and / or scan pulse width of the address period. And / or the background luminance adjustment circuit is configured to relatively widen a reset pulse width in the reset period. is there. As described above, in the present invention, the luminance adjusting unit sets the reset pulse width, address palace width and / or scan pulse width in the surplus time generated by adjusting the luminance of the plasma display panel as the ambient light intensity decreases. Since the width is increased, the contrast can be maintained without causing a reduction in the operating margin.
[0015]
In addition, the plasma display device according to the present invention, if necessary, When the intensity of the light detected by the light detection unit is relatively small, the peak luminance adjustment circuit further increases the sustain pulse width in the sustain period. is there. As described above, in the present invention, the brightness adjusting unit is adjusted by the surplus time generated by adjusting the brightness of the plasma display panel as the ambient light intensity decreases. Peak brightness adjustment circuit However, since the sustain pulse width is widened, the contrast can be maintained without degrading the operation margin.
[0016]
In addition, in the plasma display device according to the present invention, as necessary, the luminance adjustment unit may select any one of a plurality of subfields constituting one field as the intensity of light detected by the light detection unit increases. One or more subfields are deleted, and the number of sustain pulses in the sustain period is increased during the surplus time caused by the subfield deletion. As described above, in the present invention, the luminance adjustment unit deletes the subfield as the ambient light intensity increases, and the number of sustain pulses is increased by the surplus time generated by the subfield deletion. Can be significantly increased.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment of the present invention)
A plasma display apparatus according to a first embodiment of the present invention will be described with reference to FIGS. 1 is an overall block diagram of the plasma display device according to the present embodiment, FIG. 2 is a field configuration diagram of the plasma display device according to the present embodiment, FIG. 3 is a drive pulse waveform diagram of the subfield shown in FIG. These show the waveform shape change figure by control of the peak luminance adjustment circuit and the background luminance adjustment circuit in the plasma display apparatus according to the present embodiment.
[0018]
In FIG. 1, the plasma display apparatus includes a plasma display panel 1 that displays a screen by discharging, an address electrode drive circuit 2 that controls driving of address electrodes of the plasma display panel 1, and driving of an X electrode of the plasma display panel 1. An X electrode driving circuit 3 for controlling the Y electrode, a Y electrode driving circuit 4 for controlling the driving of the Y electrode of the plasma display panel 1, and ambient light of the plasma display panel 1 (hereinafter referred to as "ambient light" as "ambient light"). )), A peak luminance adjustment circuit 61 that can adjust the peak luminance based on the intensity of ambient light detected by the light detection circuit 5, and the light detection circuit 5. And a luminance adjustment circuit 6 comprising a background luminance adjustment circuit 62 capable of adjusting the background luminance based on the intensity of the ambient light. It is a configuration that.
[0019]
The light detection circuit 5 is disposed around the plasma display panel 1 so that ambient light of the plasma display panel 1 can be detected. For example, an illuminance sensor using a phototransistor is used. This is because the phototransistor is a relatively small element and does not require a large area for the plasma display device. Furthermore, this is because the phototransistor has a sensitivity close to a human's specific visual sensitivity peak, and is used for liquid crystal backlight control, camera strobe control and the like. When the photodetection circuit 5 detects the intensity of ambient light of the plasma display panel 1 using a phototransistor, it outputs the intensity of light as a detection result to the peak luminance adjustment circuit 61 and the background luminance adjustment circuit 62.
[0020]
The peak luminance adjusting circuit 61 can control the X electrode driving circuit 3 and the Y electrode driving circuit 4 in order to adjust the peak luminance based on the light intensity detected by the light detection circuit 5, and the light intensity can be controlled. When the light intensity is large, the number of sustain pulses is increased, and when the light intensity is small, the number of sustain pulses is decreased. The control of the sustain pulse based on the light intensity by the peak luminance adjustment circuit 61 divides the light intensity into several stages, and the number of sustain pulses is determined corresponding to the section. This control may be realized by a circuit, or may be realized by separately providing a ROM and reading the number of sustain pulses from the ROM using the intensity of light as a key.
[0021]
The background luminance adjustment circuit 62 can control the X electrode driving circuit 3, the Y electrode driving circuit 4, and the address electrode driving circuit 2 in order to adjust the background luminance based on the light intensity detected by the light detection circuit 5. When the light intensity is low, the voltage level of the reset pulse is reduced. The control of the reset pulse based on the light intensity by the background luminance adjustment circuit 62 divides the light intensity into several stages as in the peak luminance adjustment circuit 61, and the voltage level of the reset pulse is determined corresponding to the division. So that This control may be realized by a circuit, or may be realized by separately providing a ROM and reading the voltage level of the reset pulse from the ROM using the intensity of light as a key.
[0022]
In the plasma display device, as shown in FIG. 2, gradation display is performed by dividing one field into a plurality of subfields and controlling the number of sustain pulses for the cell. As shown in FIG. 3, each subfield has a reset period for making the wall charges of all the cells uniform, an address period for selecting (discharging) a lighting cell for display, and a discharge of the selected lighting cell. It consists of a sustain period to maintain.
[0023]
The case where the operation of the plasma display device according to the present embodiment in the above configuration is performed in a plurality of environments (under sunlight, under a fluorescent lamp, and under a dark room) will be described. Here, for convenience, the light intensity classifications in the peak luminance adjustment circuit 61 and the background luminance adjustment circuit 62 are classified into L1 (light intensity is large, for example, light intensity under sunlight), and L2 (light intensity is large). Neither small nor small, for example, the intensity of light under a fluorescent lamp is smaller than the intensity of L1 light, and L3 (the intensity of light is small, for example, the intensity of light in a dark room is smaller than the intensity of light of L2). There are three stages. This division can be set at an arbitrary stage. From the standpoint of maintaining a constant contrast, the higher the number of stages, the higher the accuracy of maintaining the contrast.
[0024]
First, a case where the plasma display device is operated in an environment under a fluorescent lamp will be described. The photodetection circuit 5 detects the intensity of ambient light around the plasma display panel 1 by using a phototransistor, and outputs the intensity of light as a detection result to the peak luminance adjustment circuit 61 and the background luminance adjustment circuit 62. In this case, the light detection circuit 5 only detects the light intensity when the change in the light intensity frequently changes in a short time, and does not output the detection result to the peak luminance adjustment circuit 61 and the background luminance adjustment circuit 62. It is also possible to prevent unnecessary control of the peak luminance adjustment circuit 61 and the background luminance adjustment circuit 62 when the ambient light is not stable.
[0025]
The peak luminance adjustment circuit 61 determines that the intensity of ambient light of the plasma display panel 1 input from the light detection circuit 5 is the section L2, and determines in advance that the number of sustain pulses corresponding to the section L2 is the normal number of sustain pulses. Therefore, the X electrode driving circuit 3 and the Y electrode driving circuit 4 are controlled in the sustain period with the normal number of sustain pulses.
Further, the background luminance adjustment circuit 62 determines that the ambient light intensity of the plasma display panel 1 input from the light detection circuit 5 is the section L2, and the voltage level of the reset pulse corresponding to the section L2 is the normal reset pulse. Since the voltage level is set in advance, the X electrode driving circuit 3 and the Y electrode driving circuit 4 are controlled in the reset period by the reset pulse at the normal voltage level.
[0026]
Next, a case where the plasma display device is operated in an environment under sunlight will be described. The photodetection circuit 5 detects the intensity of ambient light of the plasma display panel 1 by using a phototransistor, and outputs the intensity of light as a detection result to the peak luminance adjustment circuit 61 and the background luminance adjustment circuit 62.
The peak luminance adjustment circuit 61 determines that the ambient light intensity of the plasma display panel 1 input from the light detection circuit 5 is the section L1, and the sustain of the section L1 in which the number of sustain pulses is increased as compared with the section L2. The X electrode drive circuit 3 and the Y electrode drive circuit 4 are controlled in the sustain period by the number of pulses.
[0027]
The background luminance adjustment circuit 62 determines that the ambient light intensity of the plasma display panel 1 input from the light detection circuit 5 is the section L1, and the section L1 is set to the same voltage level as the reset pulse of the section 2 The X electrode driving circuit 3 and the Y electrode driving circuit 4 are controlled in the reset period by the reset pulse. In this way, by controlling the X electrode drive circuit 3 and the Y electrode drive circuit 4 with the number of sustain pulses increased from the normal level (section L2), the peak luminance increases, and a constant contrast is maintained even if the ambient light is bright. Is possible.
[0028]
Next, a case where the plasma display device is operated in an environment in a dark room will be described. The photodetection circuit 5 detects the intensity of ambient light around the plasma display panel 1 by using a photo-trasis, and outputs the intensity of light as a detection result to the peak luminance adjustment circuit 61 and the background luminance adjustment circuit 62.
The peak luminance adjustment circuit 61 determines that the ambient light intensity of the plasma display panel 1 input from the light detection circuit 5 is in the section L3, and the sustain of the section L3 in which the number of reset pulses is reduced as compared with the section 2 The X electrode drive circuit 3 and the Y electrode drive circuit 4 are controlled in the sustain period by the number of pulses (see FIG. 2).
[0029]
Further, the background luminance adjustment circuit 62 determines that the ambient light intensity of the plasma display panel 1 input from the light detection circuit 5 is the section L3, and the voltage level is lower than the reset pulse of the section L2. The X electrode driving circuit 3 and the Y electrode driving circuit 4 are set in the reset pulse of the section L3 (FIG. 4A shows a normal reset pulse waveform, and FIG. 4A ′ shows a reset pulse waveform having a low voltage level). Control during the reset period. By controlling the X electrode drive circuit 3 and the Y electrode drive circuit 4 in a state where the number of sustain pulses is decreased from the normal level (section L2), the peak luminance is reduced, and the voltage level of the reset pulse is set to the normal level (section L2). The background luminance is reduced by controlling the X electrode driving circuit 3 and the Y electrode driving circuit 4 at a lower level, and a constant contrast can be maintained even when the ambient light is dark.
[0030]
As described above, according to the plasma display apparatus according to the present embodiment, when the ambient light of the plasma display panel 1 is bright, the X electrode driving circuit 3 and the Y electrode driving are performed with the number of sustain pulses increased by the peak luminance adjusting circuit 61. Since the circuit 4 is driven, it is possible to maintain a constant contrast even when the peak luminance is increased and the ambient light is bright. When the ambient light of the plasma display panel 1 is dark, the peak luminance adjustment circuit 61 reduces the number of sustain pulses. Since the X electrode driving circuit 3 and the Y electrode driving circuit 4 are driven in a state where the peak luminance is reduced, the address luminance driving circuit 2 and the X electrode are reduced with the background luminance adjusting circuit 62 reducing the voltage level of the reset pulse. Since the drive circuit 3 and the Y electrode drive circuit 4 are driven, the background luminance is reduced and Both dark and light can be maintained constant contrast.
[0031]
(Second embodiment of the present invention)
A plasma display device according to a second embodiment will be described with reference to FIGS.
The plasma display apparatus according to the present embodiment is configured in the same manner as the plasma display apparatus according to the first embodiment, and the address electrode driving is performed so that the peak luminance adjustment circuit 61 widens the address pulse and the scan pulse in the address period. The control of the circuit 2 and the Y electrode drive circuit 4 is different.
[0032]
When the peak luminance adjustment circuit 61 receives the ambient light intensity of the plasma display panel 1 from the light detection circuit 5 and decreases the number of sustain pulses in order to reduce the peak luminance when the light intensity is smaller than normal. In addition, extra time is generated in one field. The address pulse or scan pulse in the address period is widened during this surplus time. Thus, by widening the address pulse or the scan pulse in the address period, highly accurate addressing can be performed.
[0033]
Next, the operation of the plasma display device according to the present embodiment will be described. However, only the case where the plasma display device is operated in a dark room environment will be described, and the other cases operate in the same manner as in the first embodiment. .
The photodetection circuit 5 detects the intensity of ambient light of the plasma display panel 1 by using a phototransistor, and outputs the intensity of light as a detection result to the peak luminance adjustment circuit 61 and the background luminance adjustment circuit 62. The peak luminance adjustment circuit 61 determines that the ambient light intensity of the plasma display panel 1 input from the light detection circuit 5 is the section L3, and the number of sustain pulses corresponding to the section L3 is decreased from the normal (section L2). This is the number of sustain pulses, and the X electrode drive circuit 3 and the Y electrode drive circuit 4 are controlled by the number of sustain pulses, and the surplus time generated by reducing the number of sustain pulses in the sustain period is used to address the address period. The pulse and scan pulse are widened (FIG. 4B shows a normal address pulse waveform and scan pulse waveform, and FIG. 4B ′ shows a widened address pulse waveform and scan pulse waveform). 2 and Y electrode drive circuit 4 are controlled. The background luminance adjustment circuit 62 determines that the ambient light intensity of the plasma display panel 1 input from the light detection circuit 5 is the section L3, and the reset pulse corresponding to the section L3 is lower than the normal (section L2). The X electrode drive circuit 3 and the Y electrode drive circuit 4 are controlled at the voltage level.
[0034]
In this way, by controlling the X electrode drive circuit 3 and the Y electrode drive circuit 4 with the number of sustain pulses decreased from the normal state, the peak luminance is reduced, and the voltage level of the reset pulse is lower than normal (section L2). Since the background luminance is reduced by controlling the X electrode driving circuit 3 and the Y electrode driving circuit 4, the constant contrast can be maintained even when the ambient light is dark, and the address pulse and scan pulse in the address period are wide. Since the address electrode drive circuit 2 and the Y electrode drive circuit 4 are controlled as described above, it is possible to ensure the reliable selection of the lighting cells even though the voltage level of the reset pulse is lower than the normal level (section L2). Therefore, it is possible to prevent the operation margin from being lowered.
[0035]
(Third embodiment of the present invention)
A plasma display device according to a third embodiment will be described with reference to FIGS.
The plasma display apparatus according to the present embodiment is configured in the same manner as the plasma display apparatus according to the first embodiment, and the X electrode driving circuit 3 and the peak luminance adjusting circuit 61 are configured to widen the sustain pulse during the sustain period. The Y electrode drive circuit 4 is controlled differently.
[0036]
The peak luminance adjustment circuit 61 receives the intensity of ambient light of the plasma display panel 1 from the photodetection circuit 5 and reduces the number of sustain pulses in order to reduce the peak luminance when the light intensity is smaller than normal. In addition, extra time is generated in one field. The sustain pulse in the sustain period is widened during this surplus time. Thus, by widening the sustain pulse in the sustain period, it is possible to surely discharge the lighting cell selected by the addressing.
[0037]
Next, the operation of the plasma display device according to the present embodiment will be described. However, only the case where the plasma display device is operated in a dark room environment will be described, and the other cases are the same as those in the first embodiment.
The photodetection circuit 5 detects the intensity of ambient light of the plasma display panel 1 by using a phototransistor, and outputs the intensity of light as a detection result to the peak luminance adjustment circuit 61 and the background luminance adjustment circuit 62. The peak luminance adjustment circuit 61 determines that the ambient light intensity of the plasma display panel 1 input from the light detection circuit 5 is the section L3, and the number of sustain pulses corresponding to the section L3 is decreased from the normal (section L2). This is the number of sustain pulses, and the X electrode drive circuit 3 and the Y electrode drive circuit 4 are controlled by the number of sustain pulses, and the surplus time generated by reducing the sustain pulse in the sustain period is used to maintain the sustain pulse between the synchronization periods. (FIG. 4C shows a normal sustain pulse waveform, and FIG. 4C ′ shows a widened sustain pulse waveform.) The X electrode drive circuit 3 and the Y electrode drive circuit 4 are controlled. Hereinafter, the control of the X electrode drive circuit 3 and the Y electrode drive circuit 4 relating to the voltage level of the reset pulse by the background luminance adjustment circuit 62 is the same as in the second embodiment.
[0038]
By controlling the X electrode drive circuit 3 and the Y electrode drive circuit 4 with the number of sustain pulses reduced as described above, the peak luminance is reduced, and the X pulse drive is performed with the reset pulse voltage level lower than usual. By controlling the circuit 3 and the Y electrode drive circuit 4, the background luminance is reduced, so that a constant contrast can be maintained even when the ambient light is dark, and the sustain pulse in the sustain period is widened to make the X electrode drive circuit 3 Since the Y electrode drive circuit 4 is controlled, it is possible to generate a sustain discharge that reliably takes over the discharge of the lighting cell selected in the address period despite the fact that the voltage level of the reset pulse is lower than usual. It is possible to prevent the operation margin from being lowered.
[0039]
(Other embodiments of the present invention)
In the plasma display device according to each of the embodiments described above, surplus occurs when the peak luminance adjustment circuit 61 controls the X electrode drive circuit 3 and the Y electrode drive circuit 4 by reducing the number of sustain pulses in the sustain period from the normal level. The reset pulse of the reset period can be widened in time, and a predetermined amount of wall charges can be reliably formed at a predetermined location of the plasma display panel 1.
[0040]
Further, in the plasma display device according to each of the embodiments, when the intensity of ambient light is small, the background luminance adjustment circuit 62 uses the reset pulse voltage level lower than normal to set the X electrode drive circuit 3 and the Y electrode drive circuit 4. Although the background brightness was reduced by controlling the sub-field, the sub-fields constituting the field can also be deleted, and the background brightness can be similarly reduced by reducing the number of times of light emission in the reset period by deleting the sub-field. You can also. In addition, each pulse can be widened by the surplus time generated by deleting the subfield, and the operation margin can be maintained.
[0041]
In the plasma display device according to each of the embodiments, when the intensity of ambient light is large, the subfields constituting the field are deleted, and the luminance adjustment unit performs the sustain pulse with the surplus time generated by the subfield deletion. The number can be increased, and the peak luminance can be increased to obtain a higher contrast.
[0042]
【The invention's effect】
As described above, in the present invention, since the luminance adjustment unit adjusts the background luminance based on the intensity of ambient light detected by the light detection unit, the contrast determined from the peak luminance and the background luminance is constant under any environment. There is an effect that it can be maintained.
[0043]
In the present invention, the brightness adjusting unit changes at least one of the pulse shape, the number of subfields, and the number of sustain pulses according to the intensity of ambient light detected by the light detection unit. Accordingly, the peak luminance and / or the background luminance can be changed, and the contrast can be reliably maintained at a certain level or more.
[0044]
Further, in the present invention, the brightness adjustment unit reduces the background brightness as the ambient light decreases, so when displaying a dark part on the panel under a dark room, it can be displayed with an appropriate brightness that is not too bright, A certain level of contrast can be maintained.
[0045]
Further, in the present invention, the luminance adjustment unit decreases the peak luminance as the intensity of ambient light decreases, so that when displaying a bright part on the panel in a dark room, display with an appropriate luminance that is not too bright is possible. It has the effect of being able to.
[0046]
In the present invention, as the intensity of ambient light decreases, the luminance adjusting unit lowers the voltage level of the reset pulse, so that the background luminance can be reduced.
[0047]
In the present invention, the luminance adjustment unit decreases the number of sustain pulses in the sustain period as the intensity of ambient light decreases, so that the peak luminance can be reduced without reducing the number of gradations. It has the effect.
[0048]
Further, in the present invention, the luminance adjusting unit widens the reset pulse width, the address palace width and / or the scan pulse width in the surplus time generated by adjusting the luminance of the plasma display panel as the ambient light intensity decreases. As a result, the contrast can be maintained without degrading the operation margin.
[0049]
Further, in the present invention, the brightness adjustment section widens the sustain pulse width in the surplus time generated by adjusting the brightness of the plasma display panel as the ambient light intensity decreases, so that the operation margin is reduced. Therefore, the contrast can be maintained.
[0050]
In the present invention, as the ambient light intensity increases, the brightness adjusting unit deletes the subfield, and the number of sustain pulses is increased by the surplus time generated by the deletion of the subfield. It has the effect that it can be enlarged.
[Brief description of the drawings]
FIG. 1 is an overall block configuration diagram of a plasma display device according to each embodiment of the present invention.
FIG. 2 is a field configuration diagram of a plasma display device according to each embodiment of the present invention.
FIG. 3 is a drive pulse waveform diagram of the subfield shown in FIG. 2;
FIG. 4 is a waveform shape change diagram controlled by a peak luminance adjustment circuit and a background luminance adjustment circuit in the plasma display device according to each embodiment of the present invention.
FIG. 5 is an overall block configuration diagram of a conventional plasma display apparatus.
FIG. 6 is a field configuration diagram of a conventional plasma display device.
FIG. 7 is a field configuration diagram of a conventional plasma display device.
FIG. 8 is a field configuration diagram of a conventional plasma display device.
[Explanation of symbols]
1,101 Plasma display panel
2,102 Address electrode drive circuit
3, 103 X electrode drive circuit
4, 104 Y electrode drive circuit
5 Photodetection circuit
61 Peak brightness adjustment circuit
62 Background brightness adjustment circuit
105 Ambient light detection circuit
106 frame memory
107 Memory write control circuit
108 Memory read control circuit
109 Drive pulse generation circuit
110 Subfield sustain discharge frequency control circuit
111 Field pause period detection circuit
112 Rest period rearrangement control circuit

Claims (3)

A plasma display panel in which a first substrate on which a main electrode is disposed and a second substrate on which an address electrode is disposed is arranged to face each other via a discharge space. The plasma display panel includes a reset period and an address period. In a plasma display device that displays halftones by a plurality of subfields composed of a sustain period,
Based on the light detection unit that detects the intensity of ambient light of the plasma display panel and the light intensity that is the detection result of the light detection unit, the peak luminance of the display surface displayed on the plasma display panel can be adjusted A luminance adjustment unit comprising a peak luminance adjustment circuit and a background luminance adjustment circuit capable of adjusting the background luminance of the display surface;
The peak luminance adjustment circuit calculates the number of sustain pulses in the sustain period when the intensity of the light detected by the light detection unit is the intensity of the light of the second section larger than the intensity of the light of the first section. While the light intensity is increased as compared with the light intensity of the first section, the light intensity given from the light detection unit is smaller than the light intensity of the first section . If the light intensity of the section, the number of sustain pulses in the sustain period is made smaller than when the light intensity is the light intensity of the first section ,
When the intensity of light detected by the light detection unit is the intensity of light in the third section, which is smaller than the intensity of light in the first section, the background luminance adjustment circuit has a reset pulse in the reset period. The plasma display device is characterized in that the voltage level of the plasma display device is made lower than when the light intensity is the light intensity of the first section . The plasma display device according to claim 1, wherein
When the light intensity detected by the light detection unit is the light intensity of the third section that is smaller than the light intensity of the first section , the peak luminance adjustment circuit further includes an address in the address period. The width and / or the scan pulse width is made wider than the case where the light intensity is the light intensity of the first section , and / or the background luminance adjustment circuit is configured to reset the reset pulse in the reset period. A plasma display device characterized in that the width is made wider than when the light intensity is the light intensity of the first section . The plasma display device according to claim 1 or 2,
When the intensity of the light detected by the light detection unit is the intensity of the light of the third section that is smaller than the intensity of the light of the first section , the peak luminance adjustment circuit further includes a sustain pulse in the sustain period. A plasma display device characterized in that the width is made wider than when the light intensity is the light intensity of the first section .

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