JP4969868B2 - Self-luminous display image display method and image display apparatus - Google Patents

Description

  The present invention relates to an image display method and an image display device for a self-luminous display, and more particularly to an image display method and an image display device suitable for application to a portable terminal using a battery as a power source.

  2. Description of the Related Art In recent years, mobile terminals such as mobile phones that are equipped with functions associated with image display such as an e-mail function, a web browsing function, a game function, a shooting function, an image playback function, and a television broadcast reception function have become widespread.

  In such a portable terminal, a liquid crystal display is generally mounted as a display for displaying an image. Recently, a display mounted with an organic EL display in which self-luminous organic EL elements are arranged in a matrix is proposed. Has been.

  Since this organic EL display can emit light in a single color such as green (G), blue (B), red (R), etc., by combining organic EL elements that emit different colors, A multi-color display with brightness and wide viewing angle can be configured, and since a backlight like a liquid crystal display is not required, there is an advantage that a portable terminal equipped with this can be made thin and power-saving. .

  However, when an organic EL display is mounted on a portable terminal, the organic EL display cannot be driven by a battery voltage of one cell such as a lithium ion battery loaded in the portable terminal, so a booster circuit that boosts the battery voltage is required. As a result, power consumption increases and battery usage time is shortened.

  On the other hand, an organic EL display consumes more power as an organic EL element having higher emission luminance. Therefore, the higher the proportion of pixels having a higher luminance value in all pixels, the higher the power consumption.

  Therefore, it is most effective to reduce the power consumption of the organic EL display in order to further reduce the power consumption of the portable terminal on which the organic EL display is mounted and to extend the usage time of the battery.

  As one of the methods, for example, the character in the display information is corrected to white and the background of the character is corrected to black so that the average luminance of the background in the display information is lower than the average luminance of the character. It is known (see, for example, Patent Document 1).

  As another method, each organic EL element is connected to a power supply unit via a luminance adjustment switch, and the luminance cycle is changed regardless of gradation control by changing the duty cycle of the luminance adjustment switch in synchronization with the video signal. There is also known one that adjusts (see, for example, Patent Document 2).

Japanese Patent Laid-Open No. 2002-199078 JP 2003-108073 A

  According to the method disclosed in Patent Document 1, since the ratio of pixels having a high luminance value in all pixels can be reduced, the power consumption of the entire organic EL display can be reduced.

  However, a booster circuit mounted on a portable terminal is generally composed of a DC-DC converter that is a switching regulator, and its power supply efficiency has characteristics as shown in FIG. 10, for example.

  That is, as apparent from FIG. 10, in the booster circuit composed of the DC-DC converter, the power supply efficiency is improved as the input / output voltage difference is smaller when the current consumption of the load is the same. Therefore, even when the current consumption increases due to a decrease in the output voltage, the power supply efficiency is improved and the power consumption of the entire circuit is reduced. FIG. 10 shows the power supply efficiency characteristics depending on the output voltage and current consumption when the input voltage is constant at 3.3V.

  For this reason, in the method disclosed in Patent Document 1, if the output voltage of the booster circuit is constant, the power consumption of the entire organic EL display is reduced, but the power supply efficiency of the booster circuit is reduced, and as a result, at the battery end. In some cases, a sufficient power saving effect cannot be expected.

  In the method disclosed in Patent Document 2, the brightness is adjusted by changing the duty cycle of each organic EL element by changing the duty cycle by turning on / off the brightness adjustment switch connected to the power supply unit in synchronization with the video signal. Therefore, the power consumption of each organic EL element during the power-on period can be reduced.

  However, in this case, since the voltage needs to be applied to each organic EL element during the maximum period during the ON period, the current value changes on the output side of the booster circuit. For this reason, as in the case of the above-described Patent Document 1, the power supply efficiency of the booster circuit is lowered, and as a result, a sufficient power saving effect may not be expected at the battery end.

  The above-described problem of power saving is particularly serious when a battery is used as a power source. However, a DC power source that rectifies a commercial power source is used, and an output voltage is boosted by a booster circuit to drive an organic EL display. The case is equally important. The same applies to the case where other self-luminous displays such as LED displays are driven using a booster circuit as well as organic EL displays.

  Accordingly, an object of the present invention made in view of such circumstances is to provide a self-luminous display image display method and an image display apparatus capable of effectively reducing the overall power consumption including the booster circuit.

The invention of the image display method of the self-luminous display according to claim 1 that achieves the above object is to boost a DC power supply voltage by a booster circuit and drive the self-luminous display by the output voltage to display image data. A voltage value is derived according to the average brightness of the image data, the output voltage from the booster circuit is controlled according to the voltage value, and the brightness of the entire self-luminous display is controlled according to the output voltage. Then , the voltage value of the image data to be displayed next is compared with the voltage value of the image data currently being displayed, and when the voltage value of the image data to be displayed next is smaller than the voltage value of the image data currently being displayed, A value lower than the voltage value of the image data to be displayed next is set to the voltage value of the image data to be displayed next, and the voltage value of the image data to be displayed next is equal to the voltage value of the currently displayed image data. If the voltage value of the image data currently displayed is set to the voltage value of the image data to be displayed next, and the voltage value of the image data to be displayed next is larger than the voltage value of the image data currently being displayed, And a step of setting the voltage value of the image data to be displayed as it is to the voltage value of the image data to be displayed next.

Furthermore, the invention of the image display device according to claim 2 that achieves the above object is provided with a booster circuit that boosts a DC power supply voltage and a self-luminous display that displays image data by a drive circuit driven by the output voltage. In the obtained image display device, a voltage value is derived according to the average luminance of the image data, the output voltage from the booster circuit is controlled according to the voltage value, and the luminance of the entire self-luminous display according to the output voltage there be one that is controlled, by comparing the next voltage value of the image data to be displayed and the voltage value of the image data currently displayed, then the voltage value of the image data to be displayed is the image data currently displayed If the voltage value is smaller than the voltage value of the image data to be displayed next, the voltage value of the image data to be displayed next is set to the voltage value of the image data to be displayed next and the image currently being displayed. The voltage value of the currently displayed image data is set to the voltage value of the image data to be displayed next, and the voltage value of the image data to be displayed next is the same as that of the currently displayed image data. And a means for setting the voltage value of the next image data to be displayed as it is to the voltage value of the image data to be displayed next when the voltage value is larger than the voltage value.

  According to the present invention, the set voltage of the image data to be displayed next is determined based on the voltage corresponding to the image data being currently displayed and the voltage corresponding to the image data to be displayed next. The data was displayed. As a result, the set voltage corresponding to the image data to be displayed can be determined, so that the overall power consumption including the booster circuit can be effectively reduced.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
First, the configuration of the image display apparatus according to the embodiment of the present invention will be described. FIG. 1 is a block diagram illustrating a schematic configuration of the image display apparatus.

  This image display apparatus is mounted on a portable terminal such as a mobile phone or a PDA, and uses a battery 11 such as a lithium ion battery as a power source, and a DC-DC converter that is a switching regulator using the power supply voltage of the battery 11 as a switching regulator. The voltage is boosted by a booster circuit 12 having a pixel, and an organic EL display 13, which is a self-luminous display in which a large number of pixels composed of a plurality of self-luminous organic EL elements are arranged in a matrix, is driven by the output voltage. Data is displayed. Although not shown, the organic EL display 13 has a drive circuit.

  When the image data is input, the CPU 14 supplies the image data to the signal processing unit 15, performs necessary signal processing in the signal processing unit 15, and supplies the signal processed image data to the organic EL display 13.

  The signal processing unit 15 applies the output voltage of the booster circuit 12 to the organic EL display 13 by turning it on / off in synchronization with the display timing of image data of sequential frames, and also applies the voltage application timing signal or vertical synchronization. A signal is supplied to the CPU 14.

  Further, the CPU 14 sets a voltage value controlled by the booster circuit 12 for the frame in synchronization with the display timing of the frame of the input image data, and sends a voltage control signal based on the voltage value to the booster circuit 12. And the output voltage of the booster circuit 12 is controlled. The output voltage control of the booster circuit 12 by the voltage control signal from the CPU 14 is executed in synchronization with the off period of voltage application to the organic EL display 13 by the voltage application timing signal from the signal processing unit 15 or the vertical synchronization signal. To do.

  For this reason, in the present embodiment, the CPU 14 is provided with the voltage setting means 16 and the RAM 17, and the signal processing unit 15 is provided with the frame buffer 18 for one frame. Here, the voltage setting means 16 sets a voltage value in units of frames in the input image data, and supplies the image data of the frame in which the voltage value is set to the signal processing unit 15. This image data is temporarily stored in the frame buffer 18 of the signal processing unit 15 and then displayed on the organic EL display 13 in synchronization with the voltage control signal sent out by the voltage setting means 16.

  The RAM 17 stores a set voltage table necessary for the voltage setting means 16 to set a voltage value based on the image data. FIG. 2 is a diagram illustrating a set voltage table for the average luminance value. For example, the voltage setting unit 16 calculates a luminance average value for each frame of the input image data, acquires a voltage value corresponding to the luminance average value using a setting voltage table stored in the RAM 17, and acquires this voltage value. A voltage control signal based on the voltage value is sent to the booster circuit 12. Therefore, in this embodiment, the display control means is configured to include the CPU 14, the signal processing unit 15, and the booster circuit 12.

  In the set voltage table shown in FIG. 2, the voltage value at the luminance average value from 100% to 50% is 17V, and the voltage value at the luminance average value from 40% to 10% is gradually reduced from 16V. The reason is as follows. That is, the organic EL display 13 has a luminance change characteristic with respect to an applied voltage as shown in FIG. 3, for example. In FIG. 3, when the brightness is set to the maximum luminance (RGB 100%) and the applied voltage is set to the minimum voltage (here, 11 V), the brightness (luminance) at that time is 40% luminance (RGB40). %) Is almost the same as the brightness when the applied voltage is set to the maximum set value (here, 17 V). Therefore, when the luminance is 40% or less, even if the applied voltage is lowered and the luminance is adjusted, there is almost no sense of incongruity.

  Next, the operation of the image display apparatus shown in FIG. 1 will be described. FIG. 4 is a flowchart for explaining the operation of the image display apparatus. When the voltage setting means 16 of the CPU 14 acquires the image data to be displayed on the organic EL display 13 (step S201), the voltage setting means 16 calculates the average luminance value in the frame of the image data, and uses the setting voltage table stored in the RAM 17 to The voltage value corresponding to the average luminance value is acquired, and the voltage value of the image data currently being displayed, the voltage value of the image data to be displayed (acquired voltage value), and the timing of subsequent user operations, etc. A value is set (step S202). Further, the voltage setting unit 16 transfers the frame of the image data to the signal processing unit 15 (Step S203).

  When a voltage application timing signal synchronized with the display of the frame of image data on the organic EL display 13 is input from the signal processing unit 15, the voltage setting unit 16 sends a voltage control signal based on the set voltage value to the booster circuit 12. To do. When receiving the voltage control signal from the voltage setting unit 16, the booster circuit 12 supplies the power supply having the voltage value to the drive circuit of the organic EL display 13. Thereby, the voltage setting means 16 can change the voltage of a drive circuit via the booster circuit 12 (step S204). Then, the signal processing unit 15 displays the image data on the organic EL display 13 (step S205).

  FIG. 5 is a first display example showing the brightness (luminance) of the image data displayed on the organic EL display 13 in accordance with the voltage value set by the voltage setting means 16. Assume that the voltage values for the image data on the upper left screen and the lower left screen are voltage values (1) and (3), respectively, and these displays indicate the original brightness. The voltage setting means 16 obtains the voltage value (1) from the set voltage table of the RAM 17, performs processing for optimal display of the screen, and sets the voltage so that the luminance is about 10% lower than the voltage value (1). Set the value (2). Further, the voltage setting means 16 acquires the voltage value (3) from the set voltage table of the RAM 17 and performs a process for optimal display of the screen so that the luminance is about 10% lower than the voltage value (3). The voltage value (4) is set. This makes it possible to display a darker (lower brightness) screen than the upper left screen and the lower left screen (upper right screen and lower right screen).

  Also, in FIG. 5, it can be seen that the voltage value (1) (2) screen (upper diagram) is brighter (higher brightness) than the voltage value (3) (4) screen (lower diagram). When the brightness is reduced from the screen with the voltage value (1) to the screen (2) and the brightness is reduced from the screen with the voltage value (3) to the screen (4), the former is the brightness. The impression is that it has fallen extremely, but the latter is not so much. In other words, comparing the case where the brightness is reduced on a bright screen and the case where the brightness is reduced on a dark screen, the user is less likely to receive an impression that the brightness has been reduced on a dark screen, and the display is less likely to change. I understand that

Next, details of the operation of the image display apparatus shown in FIG. 1 will be described with reference to FIG.
In a state where image 1 is displayed on the organic EL display 13 (step S301), when a screen switching request is made by the user's operation (step S302), the CPU 14 inputs the image 2 data, and the voltage setting means 16 Acquires the voltage value of the image 2 data which is the next screen using the set voltage table of the RAM 17, and compares the voltage value of the image 2 data with the voltage value of the image 1 data currently being displayed (step S303). The magnitude relationship is determined (step S304). As a result of the determination, when the voltage value of the image 2 data is smaller than the voltage value of the image 1 data (when the image 2 is darker than the image 1), a value 1V lower than the voltage value of the acquired image 2 data is set. A voltage value of 2 data is set (step S307). Further, when the voltage value of the image 2 data is equal to the voltage value of the image 1 data (when the image 2 and the image 1 have the same brightness), the voltage value of the image 1 data being displayed, which is the previous image data, is displayed as an image. A voltage value of 2 data is set (step S305). When the voltage value of the image 2 data is larger than the voltage value of the image 1 data (when the image 2 is brighter than the image 1), the acquired voltage value of the image 2 data is directly used as the voltage value of the image 2 data. Set (step S306).

  If no user operation is detected (step S308), the voltage setting unit 16 transfers the image 2 data to the signal processing unit 15 (step S309), and the signal processing unit 15 stores the image in the frame buffer 18. When it is determined that there is no data (step S310), a voltage application timing signal is output to the CPU 14, and the voltage setting means 16 boosts the voltage control signal based on the voltage value of the image data 2 set in steps 305 to 307. The data is sent to the circuit 12 (step S311). Then, the signal processing unit 15 replaces the image 2 data with the image 1 data being displayed in step 301 and displays it on the organic EL display 13 (step S312). The image data displayed on the organic EL display 13 is overwritten as needed with the image data stored in the frame buffer 18 unless the image is updated by the user's operation, so that the display is maintained.

  In step 310, when the signal processing unit 15 determines that there is image data in the frame buffer 18 and does not detect a user operation (step S314), the processing of steps 311 and 312 described above is performed. On the other hand, if a user operation is detected in step 314, the voltage setting unit 16 resets the voltage value of the image data 2 set in steps 305 to 307 to ½. The signal processing unit 15 outputs a voltage application timing signal to the CPU 14, and the voltage setting unit 16 sends a voltage control signal based on the voltage value of the image data 2 reset in step 315 to the booster circuit 12 (step S311). ). Then, the signal processing unit 15 replaces the image 2 data with the image 1 data being displayed in step 301 and displays it on the organic EL display 13 (step S312). In this case, image display switching (image 1 → image 2 → image input by the operation in step 314) becomes faster, so it is not necessary to maintain a high luminance with respect to image 2 that is an intermediate image. Since 2 is displayed, the voltage value of the image 2 data is reduced to ½.

  On the other hand, when the operation of the user is detected in step 308, the CPU 14 inputs the image 3 data and discards the image 2 data and the voltage value of the image 2 data (step S313). Then, returning to step 303, the voltage setting means 16 compares the voltage value of the image 1 data with the voltage value of the image 3 data as the next image data, and performs the above-described processing.

  FIG. 7 is a second display example showing the brightness (luminance) of the image data displayed on the organic EL display 13 according to the voltage value set by the voltage setting means 16. This example shows that the operation of the user shifts from the display of the image 1 (upper left) to the display of the image 2 (upper center) and the display of the image 3 (upper right). The set voltage table of the RAM 17 stores the voltage value (1) for the image 1, the voltage value (2) for the image 2, and the voltage value (3) for the image 3, and the voltage value (1 )> Voltage value (2) = Voltage value (3). The lower left figure shows the display of the image 2 at the voltage value (2) (original image 2 display), and the lower right figure shows the display of the image 3 at the voltage value (3) (original image 3 display).

  When the incoming call history is selected by the user's operation while the image 1 is displayed, the voltage setting unit 16 calculates the voltage value (1) of the image 1 data and the voltage value (2) of the image 2 data. In comparison, since the voltage value (2) of the image 2 data is small, a voltage value (2) ′ that is 1V lower than the voltage value (2) of the image 2 data is set (steps 301, 302, 303, and 304 in FIG. 6). 307). Then, the signal processing unit 15 displays the image 2 (Step 312). In this case, the displayed image 2 is a darker image than the original image 2.

  When the address book is selected by the user's operation, the voltage setting means 16 compares the voltage value (2) of the image 2 data with the voltage value (3) of the image 3 data, and both values are equal. Then, the voltage value (2) ′ of the currently displayed image 2 data is succeeded as the voltage value of the image 3 data. That is, the voltage setting unit 16 sets the voltage value (2) ′ as the voltage value of the image 3 data (steps 302, 303, 304, and 305 in FIG. 6). Then, the signal processing unit 15 displays the image 3 (Step 312). In this case, the displayed image 3 is the same as the brightness of the previously displayed image 2 and is darker than the original image 3. Thus, for the user, image 1 → image 2 (darker than image 1 and darker than original image 2) → image 3 (same brightness as image 2, darker than original image 3) Displayed in order.

  FIG. 8 is a third display example showing the brightness (luminance) of the image data displayed on the organic EL display 13 in accordance with the voltage value set by the voltage setting means 16. This example shows that the display of the image 1 (left figure) is skipped from the display of the image 1 (center figure) and the display is shifted to the display of the image 3 (right figure) by the user's operation. When the incoming call history is selected by the user's operation while the image 1 is displayed, the voltage setting unit 16 calculates the voltage value (1) of the image 1 data and the voltage value (2) of the image 2 data. In comparison, since the voltage value (2) of the image 2 data is small, a voltage value (2) ′ that is 1V lower than the voltage value (2) of the image 2 data is set (steps 301, 302, 303, and 304 in FIG. 6). 307). If the user performs an operation corresponding to “OK” in the image 2 before the image 2 is displayed, the voltage setting unit 16 discards the image 2 data and the voltage value of the image 2 data. The voltage value (1) of the data is compared with the voltage value (3) of the image 3 data. Since the voltage value (3) of the image 3 data is small, the voltage value is 1V lower than the voltage value (3) of the image 3 data. (3) 'is set (steps 308, 313, 303, 304, 307). Then, the signal processing unit 15 displays the image 3 (Step 312). In this case, image 2 which is the next screen of image 1 is skipped by an operation corresponding to “OK” in image 2 described above, and image 3 darker than the original image is displayed.

  FIG. 9 is a fourth display example showing the brightness (luminance) of the image data displayed on the organic EL display 13 in accordance with the voltage value set by the voltage setting means 16. This example shows that the operation shifts to the display of image 1 (left figure), the display of image 2 (center figure), and the display of image 3 (right figure) by the user's operation. In this case, the image 2 is displayed for a very short time. When the incoming call history is selected by the user's operation while the image 1 is displayed, the voltage setting unit 16 calculates the voltage value (1) of the image 1 data and the voltage value (2) of the image 2 data. In comparison, since the voltage value (2) of the image 2 data is small, a voltage value (2) ′ that is 1V lower than the voltage value (2) of the image 2 data is set (steps 301, 302, 303, and 304 in FIG. 6). 307).

  Then, when the image 2 data is transferred to the signal processing unit 15 and the image data exists in the frame buffer 18, an operation corresponding to “OK” in the image 2 is performed by the user before the image 2 is displayed. (Steps 309, 310, and 314), the voltage setting means 16 temporarily resets the voltage value (2) ′ of the image 2 data to ½ (step 315). Then, the signal processing unit 15 displays the image 2 forcibly reduced in brightness (step 312). Further, through step 302, the voltage setting means 16 performs the operation corresponding to “OK” in the image 2 described above (step 314), and the voltage value (2) of the image 2 data and the voltage value (3) of the image 3 data. Since the two values are equal to each other, the voltage value (2) ′ of the image 2 data currently being displayed (the value before dropping to 1/2 in step 315) is succeeded as the voltage value of the image 3 data. That is, the voltage setting unit 16 sets the voltage value (2) ′ as the voltage value of the image 3 data (steps 303, 304, and 305). Then, the signal processing unit 15 displays the image 3 (Step 312). Thus, since the image 2 is displayed immediately after the image 2 is displayed and is displayed for a very short time, the voltage value of the image 2 in that case is forcibly reduced to ½, Consumption reduction can be reduced.

  As described above, according to the image display apparatus according to the embodiment of the present invention, the voltage setting unit 16 uses the set voltage table including the voltage values corresponding to the image data to be displayed. The voltage value of the drive circuit was set. Usually, the screen displayed on the organic EL display 13 is determined in advance according to the user's operation. Thereby, since a voltage value is set for each image data displayed on the organic EL display 13, it is possible to effectively reduce the power consumption of the image display device. In particular, when the image is dark, the user has an impression that the display change is small. Therefore, power consumption can be reduced without giving a sense of incongruity.

  Further, in a mobile phone or the like equipped with the image display device, when a user operates to move to a target operation screen using a hierarchical menu, to move to an operation screen pre-assigned to a button, When moving from the middle of the hierarchical menu to the operation screen, the previous screen (previous screen) may be different from the operation screen that is the transfer destination. According to the image display device according to the embodiment of the present invention, the voltage setting means 16 compares the voltage value of the image data being displayed with the voltage value of the image data to be displayed next, and the image data to be displayed next. When the image data is dark, the voltage value is lowered. When the image data is equal, the voltage value of the image data being displayed is taken over. When the image data to be displayed next is bright, the voltage value of the image data is set. Thereby, the power consumption of an image display apparatus can be reduced effectively. Further, since the output voltage of the booster circuit 12 is lowered, the power supply efficiency of the booster circuit 12 can be improved as described with reference to FIG. The power consumption at the end of the battery 11 including the entire image display device can be reduced, and the battery 11 can be used for a long time. In addition, by controlling the voltage applied to the organic EL display 13 to be lowered in this way, it is possible to expect a longer life of the organic EL display 13 itself.

  In addition, for example, when the user moves to the target operation screen using the hierarchical menu and the hierarchy becomes deeper, the operation interval by the user becomes shorter than the interval at which the operation screen is displayed. Sometimes. In this case, immediately after the image is displayed, the next image is displayed. According to the image display apparatus according to the embodiment of the present invention, the voltage setting unit 16 forcibly reduces the voltage value of the temporarily displayed image data to ½. As a result, the temporarily displayed intermediate image is displayed for a very short time as a dark image with reduced luminance. However, since the user expects the next image after the intermediate image to be displayed, the user does not feel uncomfortable with the display of the dark intermediate image. Therefore, it is possible to effectively reduce the power consumption of the image display device without giving a sense of incongruity to the user. This can be applied to an image that is displayed for a very short time when the image display is continuously switched. Further, even when the next operation is performed before the display of the next image 2 is completed, the present invention can be applied to the display of the image 2.

  It should be noted that the present invention is not limited to the above-described embodiment, and many changes or modifications can be made. For example, the output voltage control of the booster circuit 12 is not limited to the voltage application timing signal from the signal processing unit 15 and can be performed in synchronization with the vertical synchronization signal.

  In the above-described embodiment, the voltage setting unit 16 sets the voltage value of the image data using the setting voltage table stored in the RAM 17, but the data of the setting voltage table is stored in the user. It is also possible to arbitrarily set the value by storing the plurality of tables according to the factor related to the power consumption (for example, the input voltage of the booster circuit 12), and select the table according to the factor. It may be used. The voltage setting unit 16 may calculate the voltage value based on the image data using a predetermined arithmetic expression without using the set voltage table. That is, it is only necessary that the voltage value corresponding to the image data can be set.

  In the embodiment described above, the voltage setting means 16 sets the voltage value 1V lower than the voltage value acquired from the set voltage table in step 307 shown in FIG. 6, and is set in step 315. The voltage value is temporarily reset to 1/2, but is not limited to these values (1V, 1/2), and the user can arbitrarily set it. In this case, it is only necessary that the voltage value can be set or reset to a voltage value lower than the original voltage value.

  Furthermore, the present invention is not limited to an organic EL display, and can be effectively applied to other self-luminous displays such as LED displays that are driven using a booster circuit, and is also applicable to portable terminals such as cellular phones and PDAs. However, the present invention can be effectively applied to a case where a direct-current power source that rectifies a commercial power source is used and the output voltage is boosted by a booster circuit to drive a self-luminous display.

It is a block diagram which shows schematic structure of the image display apparatus which concerns on embodiment of this invention. It is a figure which shows the setting voltage table with respect to a luminance average value. It is a figure which shows the luminance change characteristic with respect to the applied voltage in an organic electroluminescent display. 3 is a flowchart illustrating an operation of the image display device illustrated in FIG. 1. It is a figure which shows the 1st display example of an image display apparatus. 3 is a flowchart showing details of the operation of the image display apparatus shown in FIG. 1. It is a figure which shows the 2nd example of a display of an image display apparatus. It is a figure which shows the 3rd example of a display of an image display apparatus. It is a figure which shows the 4th example of a display of a screen display apparatus. It is a figure which shows the power supply efficiency characteristic of the booster circuit which consists of a DC-DC converter.

Explanation of symbols

11 Battery 12 Booster Circuit 13 Organic EL Display 14 CPU
15 Signal processor 16 Voltage setting means 17 RAM
18 frame buffer

Claims (2)

When the DC power supply voltage is boosted by a booster circuit and the self-luminous display is driven by the output voltage to display image data
A voltage value is derived according to the average brightness of the image data, the output voltage from the booster circuit is controlled according to the voltage value, and the brightness of the entire self-luminous display is controlled according to the output voltage. And
The voltage value of the image data to be displayed next is compared with the voltage value of the image data currently being displayed. If the voltage value of the image data to be displayed next is smaller than the voltage value of the image data currently being displayed, If a voltage value lower than the voltage value of the image data to be displayed is set to the voltage value of the image data to be displayed next, and the voltage value of the image data to be displayed next is equal to the voltage value of the currently displayed image data, The voltage value of the image data being displayed is set to the voltage value of the image data to be displayed next. If the voltage value of the image data to be displayed next is larger than the voltage value of the image data being currently displayed, the next display is performed. Setting the voltage value of the image data as it is to the voltage value of the image data to be displayed next;
An image display method for a self-luminous display characterized by comprising: In an image display device provided with a booster circuit that boosts a DC power supply voltage and a self-luminous display that displays image data by a drive circuit driven by the output voltage,
A voltage value is derived according to the average brightness of the image data, the output voltage from the booster circuit is controlled according to the voltage value, and the brightness of the entire self-luminous display is controlled according to the output voltage. And
The voltage value of the image data to be displayed next is compared with the voltage value of the image data currently being displayed. If the voltage value of the image data to be displayed next is smaller than the voltage value of the image data currently being displayed, If a voltage value lower than the voltage value of the image data to be displayed is set to the voltage value of the image data to be displayed next, and the voltage value of the image data to be displayed next is equal to the voltage value of the currently displayed image data, The voltage value of the image data being displayed is set to the voltage value of the image data to be displayed next. If the voltage value of the image data to be displayed next is larger than the voltage value of the image data being currently displayed, the next display is performed. Means for setting the voltage value of the image data as it is to the voltage value of the image data to be displayed next;
An image display device comprising:

Images