JP4777055B2 - Display device and control method - Google Patents

Description

The present invention relates to a display device having a self-luminous element as a pixel and a control method .

  In recent years, a display device using an organic EL (electro-luminescence) element as a pixel, that is, an organic EL display has been developed. Compared with a liquid crystal display, an organic EL display has advantages such as a wide viewing angle and a reduction in thickness, but has a disadvantage of consuming a lot of power. For this reason, when it is applied to a portable terminal device, there is a problem that the battery is consumed quickly and the driving time is shortened. Therefore, a technique for reducing power consumption is required.

As a technique for reducing the power consumption of the display device, for example, there are those disclosed in Patent Document 1 and Patent Document 2 below.
All of these technologies reduce the luminance of the backlight of the liquid crystal display under certain conditions, thereby reducing power consumption. The certain condition is when a specific still image such as a color bar is displayed in Patent Document 1, and when a CM or the like is displayed in Patent Document 2.

The technique of Patent Document 3 is to reduce the luminance of the pixels constituting the display unit of the display device when a state where there is no user input operation continues for a predetermined time.
JP 2003-271106 A JP 2005-210707 A JP 2002-268601 A

In the organic EL display, when the technology disclosed in Patent Document 1 or 2 is used to reduce power consumption, a specific still image and an image other than a specific image such as a CM are displayed. Power consumption cannot be reduced. Even when the specific image is not displayed, there are some cases and portions where there is no problem in reducing the luminance. Therefore, it cannot be said that the techniques of Patent Documents 1 and 2 sufficiently reduce the power consumption. This is not limited to organic EL displays, but can also be applied to display devices using other self-luminous elements as pixels. Therefore, there is room for reducing power consumption in these display devices. Yes.
Further, with the technique disclosed in Patent Document 3, the power consumption cannot be reduced while the user's input operation is continuously performed. Therefore, the power consumption is sufficiently reduced. However, there is still room for reducing power consumption.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to further reduce power consumption.

In order to solve the above problems, the present invention employs the following means.
The display device according to the present invention includes a display unit in which each pixel is configured by a self-luminous element, and the display unit is divided into a plurality of function-specific regions, and the pixels in the function-specific region do not change for a predetermined time or more. Control means for reducing the luminance of the pixels in the function-specific region, and the function-specific region is preset with a weighting value according to the importance of display content, Based on the weighting value, the time until the brightness is reduced is controlled so that the function-specific region of the display content with higher importance is longer than the function-specific region of the display content with low importance. And

The display device according to the present invention includes a display unit in which each pixel is configured by a self-luminous element, and the display unit is divided into a plurality of function-specific regions, and the pixels in the function-specific region do not change for a predetermined time or more. Control means for reducing the luminance of the pixels in the function-specific region, and a master-slave relationship is preset in the function-specific region, and the control unit is configured to control the master-slave based on the master-slave relationship. When reducing the brightness of the function-specific area where the relationship is main, the brightness of the function-specific area where the master-slave relationship is subordinate is reduced in conjunction.

The display device according to the present invention includes a display unit in which each pixel is configured by a self-luminous element, and the display unit is divided into a plurality of function-specific regions, and the pixels in the function-specific region do not change for a predetermined time or more. Control means for reducing the luminance of the pixels in the function-specific region, and a master-slave relationship is preset in the function-specific region, and the control unit is configured to control the master-slave based on the master-slave relationship. When the luminance of the function-specific region whose relationship is main is restored, the luminance of the function-specific region whose master-slave relationship is subordinate is returned in conjunction.

The control method according to the present invention includes a display unit in which each pixel is configured by a self-luminous element, and the display unit is divided into a plurality of function-specific regions, and the pixels in the function-specific region do not change for a predetermined time or more. And a control means for reducing the brightness of the pixels in the function-specific region, wherein the time until the brightness is reduced is less important in the function-specific region. Control is performed so that the function-specific area of the display content having a higher importance is longer than the display area.

The control method according to the present invention includes a display unit in which each pixel is configured by a self-luminous element, and the display unit is divided into a plurality of function-specific regions, and the pixels in the function-specific region do not change for a predetermined time or more. And a control means for reducing the brightness of the pixels in the function-specific region, wherein the master-slave is used when reducing the brightness of the function-specific region in which the master-slave relationship is main. The brightness of the function-specific region whose relationship is subordinate is reduced in conjunction.

The control method according to the present invention includes a display unit in which each pixel is configured by a self-luminous element, and the display unit is divided into a plurality of function-specific regions, and the pixels in the function-specific region do not change for a predetermined time or more. Control means for reducing the brightness of the pixels in the function-specific region, and when returning the brightness of the function-specific region in which the master-slave relationship is main, the function-specific relationship in which the master-slave relationship is subordinate It is characterized in that the brightness of the area is restored in conjunction with it.

  According to the present invention, the display means is divided into a plurality of function-specific areas, and the function-specific areas that do not change over a predetermined time are assumed to be areas where the user is not paying attention, and the brightness of the function-specific areas is reduced. The power consumption can be further reduced without giving the user a sense of incongruity or inconvenience.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram illustrating a configuration of a mobile terminal device 100 including the display device 1 according to the present embodiment. The display device 1 includes a display unit 2 (display unit), a drive unit 3, a storage unit 4, and a control unit 5 (control unit). In addition to the display device 1, the mobile terminal device 100 includes an operation unit 6, a timer unit 7, and a transmission / reception unit 8. The display unit 2 has a predetermined number of self-luminous elements 2a such as organic ELs arranged. Each self-luminous element 2a in the display unit 2 corresponds to a pixel in image display. The drive part 3 drives each self-light-emitting element 2a.

  The storage unit 4 stores a control program executed by the control unit 5, various data necessary for execution of the control program, various applications, and calculation results when the control unit 5 executes the control program. As a feature of the display device 1, the storage unit 4 includes a function-specific region in which each pixel of the display unit 2 is divided into a plurality of groups according to display contents of various screens displayed based on the various applications, and a function-specific region. The attribute and the counter value assigned to each functional area are stored.

  The control unit 5 displays various images on the display unit 2 by processing the various images stored in the storage unit 4 based on the control program. More specifically, the control unit 5 generates an operation amount corresponding to each self-light emitting element 2a and specifying the luminance of each pixel based on various images, and outputs the operation amount to the driving unit 3. In addition, as a characteristic control process based on the control program, the control unit 5 reads the function-specific area corresponding to the application being executed, the counter value calculation process, and the function-specific area based on the counter value. Power-saving processing for

The operation unit 6 accepts an operation by the user and outputs an operation signal corresponding to the content of the operation to the control unit 5. The timer unit 7 measures time and outputs a pulse to the controller 5 every unit time. The control unit 5 calculates a counter value using the pulse input from the time measuring unit 7.
The transmission / reception unit 8 performs wireless communication with the base station regarding telephone calls, electronic mail transmission / reception, and the like under the control of the control unit 5. The voice of the caller captured by a microphone (not shown) included in the portable terminal device 100 is transmitted to the base station via the transmission / reception unit 8, and the voice of the call partner received by the transmission / reception unit 8 from the base station is the portable terminal. The sound is output to a speaker (not shown) included in the device 100 and sounded. The e-mail is transmitted from the transmission / reception unit 8 to the destination via the base station. The e-mail transmitted from the base station is received by the transmission / reception unit 8 and output to the control unit 5.

FIG. 2 is a front view of the display unit 2 showing an example of the function-specific region. The display unit 2 displays different screens depending on various applications. The function-specific areas are set for various screens corresponding to various applications, and the screen is divided into a plurality of areas according to the functions. FIG. 2A shows functional areas A to K in which the standby application screen is divided into a plurality of areas by function, and FIG. 2B shows the mail creation application screen divided into a plurality of areas by function. Areas A to I by function are shown.
The function-specific areas A to K in FIG. Area A is a content area where various contents are displayed. The area B is a state display area that displays the state of the mobile terminal device 100. On the area A, an area G for displaying the date and day of the week and an area H for displaying the time are provided. On the area B, there are provided an area C for displaying the remaining battery level, an area D for displaying the reception level, an area E for displaying the time, and an area F for displaying an icon indicating that there is an unread mail. It has been. Regions I, J, and K are regions indicating functions corresponding to the currently executing application of a general-purpose button (not shown) whose function changes according to the application included in the mobile terminal device 100.
The function-specific areas A to I in FIG. Area A is an area for displaying the contents of the mail being created. The area B is a state display area that displays the state of the mobile terminal device 100. On the area B, there are provided an area C for displaying the remaining battery level, an area D for displaying the reception level, an area E for displaying the time, and an area F for displaying an icon indicating that there is unread mail. ing. Regions G, H, and I are regions indicating functions corresponding to an application that is currently being executed by a general-purpose button (not shown) whose function changes according to the application included in the mobile terminal device 100.
FIG. 2C is a front view of a part of the display unit 2 showing an example in which the area E for displaying the time in FIGS. 2A and 2B is subdivided. The region E1 is a region indicating time, and the region E2 is a region indicating minutes.

FIG. 3 is a schematic diagram of a table that defines the attributes of each functional area shown in FIG. 3 (a) corresponds to FIG. 2 (a), FIG. 3 (b) corresponds to FIG. 2 (b), and FIG. 3 (c) corresponds to FIG. 2 (c).
In the tables shown in FIGS. 3A and 3B, the normal luminance 31 before luminance reduction control, the weight 32 indicating whether the content displayed in the area is important or minor, and the weight 32 A time 33 until the luminance determined correspondingly is reduced, a master-slave relationship 34 between the regions, a threshold 35 used for determining whether to restore the luminance, and a linkage 36 with event occurrence are defined.
In the table shown in FIG. 3C, the master-slave relationship between the area E1 and the area E2 obtained by subdividing the area E is defined.

Next, the operation of the display device 1 configured as described above will be described in detail along the flowcharts shown in FIGS. In addition, this flowchart has shown the process sequence of the control part 5 based on a control program.
FIG. 4 is a flowchart showing the flow of the luminance reduction process. First, the control unit 5 assigns each function-specific region to each function-specific region based on the time measured by the time measuring unit 7 while there is no change in the operation amount of all the pixels included in the function-specific region. The counted counter value is added. Then, for the region R in which the counter value is equal to the time defined by the time 33 (10 seconds or 30 seconds), a process of reducing the luminance of all the pixels included in the region R is performed (S401). Subsequently, the control unit 5 determines whether or not there is a region r subordinate to the region R (S402), and if not, ends the processing (No in S402). When there is a region r subordinate to the region R (Yes in S402), the control unit 5 loops the processing in S404 to S405 for all the regions r subordinate to the region R, and this luminance reduction processing for each region r. Are recursively executed (S403).

FIG. 5 is a flowchart showing a flow of processing at the time of drawing, that is, processing when there is a change in the operation amount of the pixel whose luminance is being reduced. First, the control unit 5 extracts a range (extraction range x) occupied by a pixel whose operation amount is changed among pixels in the drawing range X (S501). Subsequently, the process loops in S502 to S508 for all the regions R _i . First, the control unit 5 determines whether or not the region R _i is a region whose luminance is being reduced (S503). If the area R _i is not an area where the luminance is being reduced (No in S503), the control unit 5 proceeds to processing for the next area R _i (S507). If the area R _i is an area whose luminance is being reduced (Yes in S503), the control unit 5 acquires the threshold value 35 from the table (S504), and the number of pixels in the common part between the extraction range x and the area R _i is the threshold value. It is determined whether or not this is the case (S505). Unless the number of pixels the intersection is equal to or larger than the threshold (No in S505), the control unit 5 proceeds to the process for the next region _{R i} (S507). If the number of pixels in the common part is equal to or greater than the threshold (Yes in S505), the control unit 5 performs a luminance restoration process described later (S506). Then, the control unit 5 proceeds to the process for the next region _{R i} (S507). When the control unit 5 performs the process for all the regions R _i , the process ends.

  FIG. 6 is a flowchart showing the flow of luminance return (lighting) processing. First, the control unit 5 determines whether or not the region R whose luminance is to be restored is subordinate to another region (S601). If the region R is not subordinate to another region (No in S601), the control unit 5 returns the luminance of all the pixels included in the region R to the normal state (100%) (S602). Subsequently, the control unit 5 initializes the counter value of the region R and determines whether there is a region r subordinate to the region R (S604). When there is no region r subordinate to the region R (No in S604), the control unit 5 ends the process. When there is a region r subordinate to the region R (Yes in S604), the control unit 5 loops the processing in S605 to S607 for all the regions r subordinate to the region R, and this luminance return processing for each region r. Are recursively executed (S606). When the region R is subordinate to another region in S601 (Yes in S601), the control unit 5 determines whether or not the luminance of the non-subordinate region (main region) where the region R is subordinate is reduced. A determination is made (S608), and if it has been reduced, the process is terminated, and if it has not been reduced, the process proceeds to S602 and the process is continued.

Next, an example of luminance control according to the above configuration and processing procedure will be described by showing the display state of the display unit 2.
FIG. 7 is a front view of the display unit 2 showing an example of a series of luminance control, in which the standby application is being executed. First, the time from (a) to (b) and from (b) to (c) is 5 seconds. From (a) to (b), the areas E and H for displaying the time are changed. Next, in (b) to (c), since the regions A, B, D, F, G, I, J, and K have not changed and 10 seconds have elapsed, the luminance of these regions is reduced, and the region A The brightness of the regions C and E subordinate to is also reduced. In the region H, when the state shown in (d) after 25 seconds has elapsed from the state shown in (c), 30 seconds have passed without changing, and the luminance is reduced. When another 30 seconds elapse from (d), the state shown in (e) is reached, the date changes and the areas E, G, and H change. At this time, the brightness of the areas G and H is restored, but the brightness of the area E is not restored because the area E is subordinate to the area A.

  FIG. 8 is a front view of a part of the display unit 2 showing an example of luminance control in the region E which is subdivided and has a master-slave relationship. When the brightness of the area A which is a non-dependent area (main area) of the area E is not reduced, the area E2 is changed but the area E1 is not changed as in the change from (a) to (b). In this case, the brightness of the area E is not restored, and when both the areas E1 and E2 are changed as in the change from (b) to (c), the brightness of the area E is restored (lighted). The

FIG. 9 is a front view of a part of the display unit 2 showing an example in which the threshold 35 is related to the return of luminance. In the change of the area D for displaying the reception level from (a) to (b), there are few different parts of the image in (a) and (b), and therefore the operation amount is different in (a) and (b). The number of pixels does not exceed the value defined in the threshold 35, and the luminance is not restored. On the other hand, when the region D changes from (a) to (c), the different parts of the image are large between (a) and (c). The luminance is restored when the number of pixels with different operation amounts exceeds the value defined in the threshold 35.
However, in the case of the change from (d) to (e), the extent of the change in the region D is the same as that in the change from (a) to (c), but in the region A to which the region D is subordinate. Since the luminance is reduced, the luminance is not restored even if the number of pixels with different operation amounts exceeds the value defined in the threshold 35.

FIG. 10 is a front view of a part of the display unit 2 showing an example of cooperation between an event and luminance return control. When the transmission / reception unit 8 receives a mail, the area F changes from (a) to the state shown in (b), an icon indicating that there is unread mail is displayed in the area F, and the icon reads the mail. It continues to be displayed while there is not. As defined in the event cooperation 36 in FIG. 3, the brightness of the area F is restored (lighted) if the brightness of the pixels in the area is reduced when a mail reception event occurs.
When 10 seconds elapse without reading the mail, the region F changes from (b) to (c), and the brightness of the region F is reduced. When the mail is further received, the state changes from (c) to (d), and the brightness of the area F is restored. Here, in the state shown in (c) and the state shown in (d), there is no difference in the image, but the luminance is restored in cooperation with the event.

FIG. 11 and FIG. 12 are front views of the display unit 2 showing an example of a series of brightness control, while the mail creation application is being executed. First, the time from (a) to (b) is 10 seconds. From (a) to (b), since the areas B, D, E, F, G, H, and I have not changed and 10 seconds have elapsed, the luminance of these areas is reduced.
Next, the time from (b) to (c) is 20 seconds. From (b) to (c), since regions A and C have not changed and 30 seconds have elapsed, the luminance of these regions is reduced.
When “A” is input in (c) and the state shown in (d) is reached, the brightness of the area A is restored, and the brightness of the areas C, D, G, H, and I subordinate to the area A is also restored.
The time from (d) to (e) is 10 seconds. From (d) to (e), since the regions D, G, H, and I have not changed and 10 seconds have elapsed, the luminance of these regions is reduced. Furthermore, when changing from (d) to (e), the region E is updated, but the luminance is not restored because the number of pixels whose operation amount has changed does not exceed the value defined in the threshold 35.
The time from (e) to (f) is 10 seconds. In (f), the area D for displaying the reception level is updated, and the luminance is restored because the number of pixels whose operation amount has changed exceeds the value defined in the threshold 35.
The time from (f) to (g) is 10 seconds. Since the user does not input characters and 10 seconds have passed without changing the area A, the brightness of the area A is reduced, and the brightness of the areas C and D subordinate to the area A is also reduced.
When the standby screen shown in (g) is changed from (f) to the standby screen shown in (g) by the user's operation, the function-specific area applied to the display unit 2 is changed because the running application changes from the mail creation application to the standby application. Since the counter value assigned to each area is an initial value, the brightness of all areas is restored.

In the present embodiment, the luminance is controlled to be reduced in one step, but two or more steps may be used in implementation.
In addition, the display device of this embodiment is effective when applied to a battery-driven portable terminal device. The mobile terminal device includes, for example, a battery-powered device such as a mobile phone, a PDA, a mobile TV, and a notebook PC.

It is a block diagram which shows the structure of the display apparatus and portable terminal device in one Embodiment of this invention. It is a schematic diagram which shows the example of the area | region formed by grouping each pixel of the display part in one Embodiment of this invention on predetermined conditions. It is a schematic diagram of the table which prescribed | regulated the attribute of each function area | region of the various applications in one Embodiment of this invention. It is a flowchart which shows the flow of the brightness reduction process in one Embodiment of this invention. It is a flowchart which shows the flow of the process at the time of drawing in one Embodiment of this invention. It is a flowchart which shows the flow of the brightness | luminance restoration process in one Embodiment of this invention. It is a front view of the display surface which shows the example of a series of brightness | luminance control in one Embodiment of this invention. It is a front view of a part of a display unit showing an example of a series of brightness control when a function-specific region in one embodiment of the present invention is subdivided to have a master-slave relationship. It is a front view of a part of display part which shows the example in which a threshold value is related to the return of luminance in one embodiment of the present invention. It is a partial front view of the display part which shows the example of cooperation with the event and brightness | luminance return control in one Embodiment of this invention. It is a front view of the display surface which shows the other example of a series of brightness | luminance control in one Embodiment of this invention. FIG. 8 is a front view of a display surface showing another example of a series of luminance control in one embodiment of the present invention, following FIG. 7.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Display apparatus, 100 ... Portable terminal device, 2 ... Display part (display means), 2a ... Self-luminous element, 3 ... Drive part, 4 ... Memory | storage part, 5 ... Control part (control means), 6 ... Operation part, 7 ... Timekeeping unit, 8 ... Transmission / reception unit

Claims (6)

Display means in which each pixel is constituted by a self-luminous element;
A control unit that divides the display unit into a plurality of function-specific regions and reduces the luminance of the pixels in the function-specific region when the pixels in the function-specific region do not change for a predetermined time;
With
In the function-specific area, a weighting value according to the importance of the display content is set in advance,
Based on the weighting value, the control means is configured so that the time until the luminance is reduced is longer in the function-specific area of the display content having a higher importance than the function-specific area of the display content having a lower importance. A display device characterized by being controlled. Display means in which each pixel is constituted by a self-luminous element;
A control unit that divides the display unit into a plurality of function-specific regions and reduces the luminance of the pixels in the function-specific region when the pixels in the function-specific region do not change for a predetermined time;
With
In the function-specific area, a master-slave relationship is preset,
Based on the master-slave relationship, the control unit reduces the brightness of the function-specific region where the master-slave relationship is subordinate when the luminance of the function-specific region where the master-subordinate relationship is main is reduced. A display device. Display means in which each pixel is constituted by a self-luminous element;
A control unit that divides the display unit into a plurality of function-specific regions and reduces the luminance of the pixels in the function-specific region when the pixels in the function-specific region do not change for a predetermined time;
With
In the function-specific area, a master-slave relationship is preset,
Based on the master-slave relationship, the control unit interlocks and returns the brightness of the function-specific region where the master-slave relationship is subordinate when returning the luminance of the function-specific region where the master-subordinate relationship is main. A display device. The display means in which each pixel is constituted by a self-luminous element and the display means are divided into a plurality of function-specific areas, and when the pixels in the function-specific area do not change for a predetermined time or more, A control means for reducing the luminance of the pixel, and a control method for a display device comprising:
A control method, characterized in that the time until the luminance is reduced is controlled so that the function-specific area of display content having a higher importance is longer than the function-specific area of display content having a lower importance. Display means in which each pixel is constituted by a self-luminous element;
A control unit that divides the display unit into a plurality of function-specific regions and reduces luminance of the pixels in the function-specific region when the pixels in the function-specific region do not change for a predetermined time or more. An apparatus control method comprising:
A control method, wherein when reducing the brightness of the function-specific area where the master-slave relation is main, the brightness of the function-specific area where the master-slave relation is slave is reduced in conjunction. Display means in which each pixel is constituted by a self-luminous element;
A control unit that divides the display unit into a plurality of function-specific regions and reduces the luminance of the pixels in the function-specific region when the pixels in the function-specific region do not change for a predetermined time;
With
A control method characterized in that, when the brightness of the function-specific area where the master-slave relation is main is restored, the brightness of the function-specific area where the master-slave relation is slaved is returned in conjunction.

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