JP2010107784A - Electronic equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide electronic equipment which achieves not only reduction of power consumption related to display but also reassignment of colors of a display image by little arithmetic processing. <P>SOLUTION: The electronic equipment includes: a display part 16 which displays at least one image and requires power consumption different for every display color; acquiring parts (131, 133) which acquire usage of every color of the image displayed on the display part classified by images; a storage part 14 in which a characteristic table to show relation between the color of the image and power consumption of the color is stored; and controllers (134, 135) which successively replace the color of the image acquired by the acquiring parts in order from the color the usage of which is large with the color the power consumption of which is small based on the characteristic table, and allow the display part to display the image. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an electronic device such as a portable terminal having a display unit whose power consumption differs depending on display colors.

  Electronic devices such as portable terminals equipped with liquid crystal panels and organic EL panels are widely distributed in the market. A liquid crystal panel or an organic EL panel may have different power consumption for display depending on display color or luminance.

In particular, since power is supplied from a battery to a portable terminal or the like, it is essential to reduce power consumption for display. In view of this, there has been proposed a mobile terminal that employs a display device that reduces power consumption for display by changing the display color according to the usage state of the mobile phone.
JP 2007-114579 A

  As illustrated in FIG. 14, the portable terminal 1 disclosed in Patent Document 1 displays display colors based on power consumption data 2 relating to power consumption characteristics for each display color and usage amount 3 occupied by each display color in a display image. Is reassigned 4 to reduce power consumption for display. Note that the color reassignment means that a color with low power consumption for display is reassigned to a color having a large amount of use with respect to the display image.

  However, when the display color is changed depending on the low power consumption mode, the non-operation state, etc., it is possible to reduce the power consumption related to the display, but it is possible to reduce the power consumption in all display screens. Do not mean.

  In addition, every time the display screen is updated, color reassignment is performed by scanning all pixels on the display screen. However, in the portable terminal 1 disclosed in Patent Document 1, an operation required for color reassignment is performed. There is a disadvantage that the processing amount increases.

  An object of the present invention is to provide an electronic device that can not only reduce power consumption related to display but also reallocate colors of a display image with a small amount of arithmetic processing.

  The electronic apparatus of the present invention displays at least one image, a display unit that consumes different power for each color to be displayed, and an acquisition unit that acquires the usage amount of each color of the image displayed on the display unit for each image A storage unit that stores a characteristic table indicating a relationship between the color of the image and the power consumption of the color, and the color of the image acquired by the acquisition unit based on the characteristic table in descending order of color used And a controller that sequentially replaces colors with lower power consumption and displays the image on the display unit.

  Preferably, the image includes an image indicating an operation state of a predetermined function of the own device.

  Preferably, the display unit displays a plurality of images, the acquisition unit acquires the usage status for each image when updating the display of the display unit, and the control unit displays the image to be displayed. When an instruction for assigning a color is received, a color with low power consumption of the display unit is assigned in the order of the image with the largest change in the usage status.

  Preferably, based on the usage amount of each image for each color and the usage state of each image, the calculation unit calculates the usage amount of the color occupied by all the images, and the acquisition unit The order of the images with the large change in usage status is acquired from the calculation result by the calculation unit.

  Preferably, the control unit assigns from the order of colors associated with the power consumption of the display unit indicated by the characteristic table of the storage unit and the order of images with a large change in the usage status by the acquisition unit. Determine the color of the image to be.

  Preferably, the use state of the image includes a use time of the image, and includes a time measuring unit that measures the use time of the image for each image, and the calculation unit calculates a use amount for each color occupied by the image. At the time of calculation, the sum for each image of the product of the amount of color used and the time of use of the image by the timer is calculated for each color.

  Preferably, the usage state of the image includes the number of times of use of the image, and includes a measuring unit that measures the number of times of use of the image for each image, and the calculation unit calculates a usage amount for each color occupied by the image. At the time of calculation, the sum for each image of the product of the amount of color used and the time of use of the image by the timer is calculated for each color.

  Preferably, each image can be assigned a color for each part constituting the image, the storage unit stores color arrangement data for performing color arrangement for each part of the image, and the control unit includes: A color is assigned to each part of the image with reference to the color arrangement data of the storage unit.

  According to the present invention, not only power consumption for display can be reduced, but also the color of a display image can be reassigned with less arithmetic processing.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a schematic block diagram illustrating a configuration example of a mobile terminal according to the first embodiment of the present invention.

  A mobile terminal 10 as an electronic device illustrated in FIG. 1 includes an antenna 11, a communication unit 12, a control unit 13, a storage unit 14, a voice input / output unit 15, a speaker (SP) 15a, a microphone (MIC) 15b, and a display unit 16. , An operation unit 17, a battery 18, and a charging circuit 19.

  The mobile terminal 10 is a mobile phone in this embodiment. The mobile terminal 10 may be, for example, a PHS (Personal Handy phone System). The mobile terminal 10 has various functions including voice calls. These functions include, for example, a function related to e-mail, a browsing function of a WEB (World Wide Web) site, a function of displaying the remaining amount of the battery 18 (remaining battery amount), a function of displaying the reception state of the antenna 11, Includes the ability to display the time.

  In addition, as a feature of the present embodiment, the mobile terminal 10 has a color arrangement function that can optimize the color arrangement of the display parts displayed on the display unit 16. With this color arrangement function, power consumption for display can be minimized and the battery 18 can be saved. Display parts (images of the present invention) refer to, for example, characters, background images, title bars, icons, and the like.

  The antenna 11 is a built-in antenna in this embodiment. The antenna 11 may be a rod antenna, for example. The antenna 11 transmits or receives electromagnetic waves in a predetermined frequency band toward a base station (not shown).

  The communication unit 12 modulates the transmission signal output from the control unit 13 into a predetermined modulation method, and transmits the modulated transmission signal to the base station via the antenna 11 as a radio wave signal. The communication unit 12 demodulates the radio wave signal received from the base station via the antenna 11 and outputs the demodulated signal to the control unit 13 as a received signal.

  The control unit 13 is configured by, for example, a CPU, a DSP (Digital Signal Processor), or the like. The control unit 13 controls the overall operation of the mobile terminal 10 so that various processes are executed in an appropriate procedure according to the operation of the operation unit 17.

  The process performed by the control unit 13 includes a display part color scheme, a battery remaining amount detection, a voice call, a process for browsing an e-mail and a web, and the like.

  The control performed by the control unit 13 includes communication control of the communication unit 12, access to the storage unit 14, display of data on the display unit 16, input of characters by operation of the operation unit 17, and voice processing in the voice input / output unit 15. Control and the like.

  The storage unit 14 includes, for example, a nonvolatile storage device (flash memory), a randomly accessible storage device (SRAM, DRAM), or the like.

  The storage unit 14 stores power consumption data (characteristic table of the present invention) and a color palette (color arrangement data of the present invention). The power consumption data and the color palette are referred to when the color arrangement function is executed.

  In addition, the storage unit 14 stores an operating system, an application program, an output result of the control unit 13, temporary data used in the process of the program, and the like.

  Since the audio input / output unit 15 outputs the digital audio data supplied from the control unit 13 via the speaker 15a, the digital audio data is a signal such as digital / analog (D / A) conversion and amplification. Apply processing.

  The audio input / output unit 15 converts the analog audio signal input from the microphone 15b into digital audio data and outputs the digital audio data to the control unit 13. Therefore, the audio input / output unit 15 amplifies, analog / digital (A / A) D) Perform processing such as conversion and encoding.

  The display unit 16 is composed of, for example, a liquid crystal panel. The display part 16 can also be comprised with an organic EL (Electro-Luminescence) panel, for example. The display unit 16 displays various information corresponding to the video signal supplied from the control unit 13.

  The operation unit 17 includes a plurality of keys to which various functions such as a power key, a call key, a numeric key, a character key, a direction key, a determination key, and a call key are assigned. When these keys are operated by the user, the operation unit 17 generates a signal corresponding to the operation content and outputs the signal to the control unit 13 as a user instruction.

  The battery 18 is a rechargeable battery composed of, for example, a lithium ion battery. The battery 18 is charged with power supplied from the charging circuit 19 during charging. The battery 18 supplies power to electronic components such as the control unit 13 constituting the mobile terminal 10.

  When charging is started, the charging circuit 19 converts electric power supplied from the external power source into electric power necessary for driving the mobile terminal 10 and supplies the electric power to the battery 18.

  In the color arrangement function of the mobile terminal 10, the colors are reassigned so that the power consumption for displaying the display color of the display unit 16 is minimized. The relationship between the power consumption and the color for display when the display unit 16 is configured with a liquid crystal panel will be described.

  FIG. 2 is a schematic cross-sectional view showing an example of the structure of the display unit when the display unit according to the first embodiment of the present invention is configured by a liquid crystal panel. FIG. 2 illustrates a transmissive TFT (thin film transistor) liquid crystal panel.

  As shown in FIG. 2, a transparent electrode 162 is attached to one surface of the glass substrate 161, and a polarizing plate (polarizing filter) 163 is attached to the other surface. A transparent electrode 166 is attached to one surface of another glass substrate 164 so as to sandwich the color filter 165, and a polarizing plate 167 is attached to the other surface. These two glass substrates 161 and 164 are arranged to face each other so that the transparent electrodes 162 and 166 face each other. A liquid crystal 168 is sealed between the two glass substrates 161 and 164.

  When a voltage is applied to the two transparent electrodes 162 and 166, the molecules of the liquid crystal 168 are arranged according to the direction of the electric field generated between the transparent electrodes 162 and 166. Since the liquid crystal 168 itself does not emit light, a backlight 169 is attached to one polarizing plate 163 side. A desired image can be displayed by transmitting or blocking the light emitted from the backlight 169 through the polarizing plates 163 and 167.

  The light source color of the backlight 169 is often white. For this reason, a color filter 165 for displaying a color image is inserted between the glass substrate 164 and the transparent electrode 166, for example. The transparent electrodes 162 and 166 are configured in a matrix by a plurality of transparent electrodes so as to configure a plurality of pixels (pixels) PIX. The color filter transmits R (red), G (green), and B (blue) light corresponding to the pixel PIX.

  In the liquid crystal panel, a color image is displayed by applying a voltage to the transparent electrodes 162 and 166 in a desired region as follows. For example, when displaying white, a voltage is applied to the transparent electrodes 162 and 166 of the pixel PIX corresponding to the R, G, and B color filters 165 by an additive color mixing method.

  When displaying yellow, a voltage is applied to the transparent electrodes 162 and 166 of the pixel PIX corresponding to the R and G color filters 165. When displaying red, a voltage is applied only to the transparent electrodes 162 and 166 of the pixel PIX corresponding to the R color filter 165. In the case of displaying black, no voltage is applied to the transparent electrodes 162 and 166.

  In this way, by applying a voltage to the transparent electrodes 162 and 166 corresponding to a specific pixel PIX, a color corresponding to the resolution can be displayed. For example, when displaying white, since the voltage is applied to the transparent electrodes 162 and 166 of the pixels PIX corresponding to R, G, and B, the power consumption of the display unit 16 is maximized. Conversely, when displaying black, no voltage is applied to the transparent electrodes 162 and 166, so that the power consumption of the display unit 16 is minimized.

  Of course, the luminance can be adjusted by adjusting the intensity of light emitted by the backlight 169. In this case, the power consumption of the display unit 16 increases as the luminance increases.

  In order to reduce the thickness of the housing and further reduce power consumption, the display unit 16 can also be configured with an organic EL panel. The relationship between the power consumption and color of the display unit 16a in this case will be described with reference to FIG.

  FIG. 3 is a schematic cross-sectional view showing an example of the structure of the display unit when the display unit according to the first embodiment of the present invention is configured by an organic EL panel. In FIG. 3, the TFT, the electron transport layer, and the like are not shown.

  In the display unit 16a illustrated in FIG. 3, two glass substrates 161 and 164 are arranged to face each other so as to sandwich the light emitting layer (organic layer) 1610. A negative electrode 162 is attached between one surface of the glass substrate 161 and the light emitting layer 1610. A positive transparent electrode 166 is also attached between one surface of another glass substrate 164 and the light emitting layer 1610.

  The light emitting layer 1610 emits light spontaneously when a forward bias voltage is applied between the transparent electrodes 162 and 166. At this time, the three colors R, G, and B independently emit light corresponding to the pixel PIX. Since the organic EL panel operates at a lower voltage than the liquid crystal panel, the power consumption is lower than that of the liquid crystal panel, but the power consumption differs depending on the colors to be displayed. As in the case of the liquid crystal panel, the power consumption of the display unit 16 is the highest when displaying white, and the power consumption is lowest when displaying black.

  According to the color arrangement function of the mobile terminal 10, the power consumption related to the above-described display can be reduced by reassigning the display color. Hereinafter, the color arrangement function which is a feature of the present invention will be described.

  FIG. 4 is a schematic diagram illustrating an example of a display image of the display unit according to the first embodiment of the present invention.

  As shown in FIG. 4, a plurality of display parts (images of the present invention) P <b> 1 to P <b> 5 are displayed in the display area ARE of the display unit 16.

  The display part P1 is a main display area in which images such as characters including numbers and symbols, a standby screen, and photographs are displayed. The display part P2 indicates the remaining battery level. The display part P3 indicates a reception state of radio waves by the antenna 11. The display part P4 indicates the current time. The display part P5 indicates, for example, soft keys corresponding to applications such as “switch”, “confirm”, and “menu”.

  The display area ARE is composed of a plurality of pixels (see FIG. 2) corresponding to the resolution of the liquid crystal panel constituting the display unit 16. Therefore, each display part P1-P5 is also comprised by the some pixel. A desired color can be assigned (colored) to each display part P1 to P5 and its background. For example, white can be assigned to the background of the display part P5, and black can be assigned to characters in the display part P5.

  At this time, the color assignment (color arrangement) of each display part is performed based on the usage status of each of the display parts P1 to P5 so that the power consumption of the display unit 16 is minimized. Next, the control unit 13 that performs such color assignment will be described.

FIG. 5 is a block diagram illustrating a configuration example of the control unit according to the first embodiment of the present invention.
In the following, unless otherwise noted, arbitrary three display parts A, B, and C among the display parts P1 to P5 illustrated in FIG. 4 will be described as an example.

  As illustrated in FIG. 5, the control unit 13 includes a first usage amount acquisition unit 131, a measurement unit 132, a second usage amount acquisition unit 133, an allocation unit 134, and a display control unit 135. The first usage amount acquisition unit 131 and the second usage amount acquisition unit 133 correspond to the acquisition unit of the present invention. The measuring unit 132 corresponds to the time measuring unit of the present invention. The second usage amount acquisition unit 133 corresponds to the calculation unit of the present invention. The allocation unit 134 and the display control unit 135 correspond to the control unit of the present invention.

  The first usage amount acquisition unit 131 acquires usage amounts of colors for the display parts A to C. As a specific example, a case where the first usage amount acquisition unit 131 acquires the usage amount for each color for the display part A will be described.

  The display image generated by the image generation unit (not shown) is displayed in the display area ARE of the display unit 16 under the control of the display control unit 135. The display image includes display parts A to C. The first usage amount obtaining unit 131 obtains the color components constituting the display part A in the display image.

  At this time, the display part A shall be comprised by white, yellow, blue, red, purple, and black. When the first usage amount obtaining unit 131 obtains that the display part A is configured by these colors, the first usage amount obtaining unit 131 obtains a color usage amount indicating how many pixels each color uses.

  At this time, it is assumed that the amount of color used for the display part A is 800 pixels for white, 0 pixels for both yellow and blue, 400 pixels for red, 300 pixels for purple, and 100 pixels for black.

  The first usage amount acquisition unit 131 acquires the usage amount of the color for the display parts B and C as in the case of the display part A.

  At this time, it is assumed that the amount of color used for the display part B is 300 pixels for white, 100 pixels for yellow, 50 pixels for blue, 200 pixels for red, 0 pixels for purple, and 200 pixels for black. Assume that the usage rates of the colors for the display part C are 200 pixels for white and yellow, 0 pixels for blue, 150 pixels for red, 30 pixels for purple, and 100 pixels for black.

  The measuring unit 132 measures the usage time for each of the display parts A to C as the usage status for each of the display parts A to C. These usage times are obtained as follows. For example, the display image is appropriately updated for display parts A to C or all in accordance with the operation of the application at the time of starting the application or after the application is started.

  For this reason, the measurement unit 132 records the time at this time in the storage unit 14 every time a new display image is generated by the image generation unit. Thereby, the measurement part 132 can measure the time interval of an update, ie, use time, from the time when the last display image was produced | generated, and the time when the display image was newly produced | generated.

  At this time, the usage time of the display part A is 30 minutes, the usage time of the display part B is 20 minutes, and the time of the display part C is 10 minutes.

  The second usage amount acquisition unit 133 displays the display parts from the usage amounts of the colors for the display parts A to C by the first usage amount acquisition unit 131 and the usage times for the display parts A to C by the measurement unit 132. The total usage amount by color of A to C is acquired.

  As a specific example, a case where the second usage amount acquisition unit 133 acquires the total white usage amount in the display parts A to C will be described. As described above, the white usage amount of the display part A is 800 pixels, and the usage time is 30 minutes. The white usage amount of the display part B is 300 pixels, and the usage time is 20 minutes. The white usage amount of the display part C is 200 pixels, and the usage time is 10 minutes.

  The second usage amount acquisition unit 133 is a value obtained by multiplying the white usage amount in the display part A by the usage time, a value obtained by multiplying the white usage amount in the display part B by the usage time, and the display part C. The sum of the white usage amount and the usage time is calculated. That is, the total amount of white used is given by the following equation.

(Equation 1)
Total white usage = (800 pixels × 30 minutes) + (300 pixels × 20 minutes) + (200 pixels × 10 minutes) = 32000 (pixels × minute) (1)

  The second usage amount acquisition unit 133 also calculates the sum for the other colors as shown in equation (1). At this time, the total usage amount of yellow is 4000, the total usage amount of blue is 1000, the total usage amount of red is 17500, the total usage amount of purple is 9300, and the total usage amount of black is 8000.

  If generalized, the second usage amount acquisition unit 133 calculates the total usage amount for each color of the display parts 1 to n based on the following equation. Here, n is the number of display parts (1, 2,...).

(Formula 2)
Total use amount of each color = (Use amount of the color in the display part 1 × Use time of the display part 1)
+ (Use amount of the color in the display part 2 x use time of the display part 2)
+ (Use amount of the color in the display part 3 x use time of the display part 3)
...
+ (Use amount of the color in display part n × Use time of display part n) (2)

  Based on the total usage amount for each color by the second usage amount acquisition unit 133 and the power consumption data DAT1 read from the storage unit 14, the allocating unit 134 minimizes the power consumption of the display unit 16. Reassign colors to display parts A-C.

  Here, the power consumption data DAT1 stored in the storage unit 14 will be described. In the power consumption data DAT1, power consumption characteristics for each color relating to the power consumption of the display unit 16 are registered in advance. Each color is assigned a value associated with power consumption. As described above, white has the highest power consumption, and a value 74 is assigned to the relative value, for example. Subsequently, the power consumption decreases in the order of yellow, blue, red, purple, and black, and values 69, 65, 65, 61, and 59 are assigned to these relative values, for example.

  The assigning unit 134 sorts the colors used in the display parts A to C in order from the color with the highest total usage amount to the lowest color. At this time, it is assumed that the colors are sorted in the order of white, red, purple, black, yellow, and blue according to the acquisition result of the second usage amount acquisition unit 133 described above.

  Then, the assigning unit 134 reassigns colors with low power consumption to the sorted colors. At this time, at least, the assigning unit 134 assigns the black with the lowest power consumption to the white with the largest total usage. Then, the assigning unit 134 records the assigned color scheme setting in the storage unit 14.

  In the above-mentioned example, considering the color balance, the color with the lowest total power consumption is assigned to the color with the highest total usage, and the colors are preferably assigned to the other colors. For example, red is assigned yellow, purple is assigned white, black is assigned purple, yellow is assigned red, and blue is again assigned blue. Of course, white, red, purple, black, yellow, and blue can be assigned in the order of the power consumption colors of the power consumption data DAT1, ie, white, yellow, blue, red, purple, and black, respectively.

  The display control unit 135 displays on the display unit 16 the display parts A to C having the colors reassigned by the assigning unit 134.

  An operation relating to the color arrangement function of the control unit 13 illustrated in FIG. 5 will be described. The usage time for each of the display parts A to C is acquired when the display image is updated (referred to as an update process), and the colors of the display parts A to C are reassigned according to a user instruction (referred to as an assignment process). Hereinafter, after describing the update process, the allocation process will be described.

  FIG. 6 is a flowchart showing an operation example of update processing by the control unit according to the first embodiment of the present invention.

  As shown in FIG. 6, the update process is started. In step ST11, when the measuring unit 132 is measuring the usage time for each of the display parts A to C (YES), the measuring unit 132 performs the following operation.

  The measurement unit 132 acquires the time when a new display image is generated by an image generation unit (not shown) (step ST12), and records the time at this time in the storage unit 14 (step ST13).

  Thereafter, the image generation unit reads display parts A to C necessary for generating a display image from the storage unit 14 (step ST14).

  Again, the measuring unit 132 starts measuring the usage time of the display parts A to C (step ST15). Then, the display control unit 135 outputs the display parts A to C generated by the image generation unit in step ST14 to the display unit 16 (step ST16).

  On the other hand, if the measurement unit 132 is not measuring the usage time for each of the display parts A to C in step ST11 (NO), the process of step ST14 is executed. Then, after the process of step ST16, the update process ends.

Next, the allocation process will be described.
FIG. 7 is a flowchart showing an operation example of assignment processing by the control unit according to the first embodiment of the present invention.

  As illustrated in FIG. 7, when the control unit 13 receives an instruction signal to start the allocation process from the operation unit 17 in accordance with an instruction from the user, the control unit 13 starts the allocation process.

  When the allocation process starts, the measuring unit 132 reads the usage time for each of the display parts A to C from the storage unit 14 (step ST21). And the 1st usage-amount acquisition part 131 acquires the usage-amount of the color according to display parts AC (step ST22). The usage time for each of these display parts A to C is recorded in the storage unit 14 in the process of step ST13 illustrated in FIG.

  Thereafter, allocation unit 134 reads power consumption data DAT1 from storage unit 14 (step ST23). Then, the second usage amount acquisition unit 133 uses the color usage amounts for the display parts A to C by the first usage amount acquisition unit 131 (see step ST22) and the display parts A to C for the display parts A to C. From the usage time (see step ST21), the total usage amount for each color of the display parts A to C is acquired (step ST24).

  Thereafter, the assigning unit 134 displays based on the total usage amount for each color (see step ST24) by the second usage amount obtaining unit 133 and the power consumption data DAT1 (see step ST23) read from the storage unit 14. The colors are reassigned to the display parts A to C so that the power consumption of the unit 16 is minimized (step ST25).

  At this time, the assigning unit 134 sorts the colors used in the display parts A to C in order from the color with the highest total usage amount to the lowest color. Then, the assigning unit 134 reassigns a color with low power consumption to each color sorted in descending order of the total usage.

  The display control unit 135 displays the display parts A to C having the colors reassigned by the assigning unit 134 on the display unit 16 (step ST26). Thereafter, the assigning unit 134 records the assigned color scheme setting in the storage unit 14. The allocation process ends by the process of step ST26.

  As described above in detail, the first usage amount acquisition unit 131 acquires the usage amount of the colors for the display parts A to C, and the measurement unit 132 measures the usage time of the display parts A to C. . The second usage amount acquisition unit 133 displays the display parts from the usage amounts of the colors for the display parts A to C by the first usage amount acquisition unit 131 and the usage times for the display parts A to C by the measurement unit 132. The total usage amount by color of A to C is acquired.

  Then, the assigning unit 134 reassigns the colors to the display parts A to C based on the total use amount for each color by the second use amount obtaining unit 133 and the power consumption data DAT1 read from the storage unit 14. As a result, the power consumption for display can be minimized.

  In particular, when an organic EL panel is employed for the display unit 16, burn-in of the organic EL panel can be prevented. Furthermore, since it is not necessary to calculate the amount of color used for all pixels on the screen, the load on the control unit 13 (CPU) can be reduced, and color assignment can be optimally performed with few operations.

(Second Embodiment)
The second embodiment will be described focusing on differences from the previous embodiment.
FIG. 8 is a block diagram illustrating a configuration example of a control unit according to the second embodiment of the present invention.

  As illustrated in FIG. 8, the control unit 13a includes a first usage amount acquisition unit 131, a measurement unit 132a, a second usage amount acquisition unit 133a, an allocation unit 134, and a display control unit 135.

  In 1st Embodiment, the measurement part 132 measures the usage time according to display parts A-C as a usage condition according to display parts A-C. On the other hand, in 2nd Embodiment, the measurement part 132a measures the use frequency according to display parts A-C as a usage condition according to display parts A-C.

  Accordingly, the second usage amount acquisition unit 133a includes the usage amount of the colors for the display parts A to C by the first usage amount acquisition unit 131, and the usage count for the display parts A to C by the measurement unit 132a. To obtain the total usage amount of the display parts A to C by color.

  As a specific example, a case where the second usage amount acquisition unit 133a acquires the total white usage amount in the display parts A to C will be described. For example, the measuring unit 132a uses the white usage time of the display part A for 30 minutes, the white usage time of the display part B for 20 minutes, and the white usage time of the display part C for 10 minutes. And

  The second usage amount acquisition unit 133a has a value obtained by multiplying the white usage amount in the display part A by the usage count, a value obtained by multiplying the white usage amount in the display part B by the usage count, and the display part C. The sum of the white usage amount and the value obtained by multiplying the usage amount is calculated. That is, the total amount of white used is given by the following equation.

(Equation 3)
Total white usage = (800 pixels × 30 times) + (300 pixels × 20 times) + (200 pixels × 10 times) = 32000 (pixels × times) (3)

  The second usage amount acquisition unit 133a also calculates the sum for the other colors as shown in Equation (3). If generalized, the second usage amount acquisition unit 133a calculates the total usage amount for each color of the display parts 1 to n based on the following equation.

(Formula 4)
Total use amount of each color = (Use amount of the relevant color in display part 1 × Number of uses of display part 1)
+ (Amount of color used in display part 2 x number of uses of display part 2)
+ (Amount of color used in display part 3 x number of times display part 3 is used)
...
+ (Use amount of the color in display part n × Number of uses of display part n) (4)

  An operation related to the color arrangement function of the control unit 13a illustrated in FIG. 8 will be described. Similar to the first embodiment, update processing and allocation processing are executed. After describing the update process, the allocation process will be described.

  FIG. 9 is a flowchart showing an operation example of update processing by the control unit according to the second embodiment of the present invention.

  The update process according to the second embodiment is different from that according to the first embodiment in that the processes of steps ST11 to ST13 illustrated in FIG. 6 are not executed. As illustrated in FIG. 9, after the update process is started, the image generation unit reads display parts A to C necessary for generating a display image from the storage unit 14 (step ST14).

  Thereafter, the measuring unit 132 measures the number of times the display parts A to C are used, and then records the number of times used in the storage unit 14 (step ST15a). Then, the display control unit 135 outputs the display parts A to C generated by the image generation unit in step ST14 to the display unit 16 (step ST16).

Next, the allocation process will be described.
FIG. 10 is a flowchart showing an operation example of assignment processing by the control unit according to the second embodiment of the present invention.

  In the allocation process according to the second embodiment, the processes of step ST21a and step ST24a are different from those according to the first embodiment. As illustrated in FIG. 10, the measuring unit 132a reads the number of times of use for each of the display parts A to C from the storage unit 14 (step ST21a).

  After the process of step ST23, the second usage amount acquisition unit 133a uses the color usage amounts for the display parts A to C by the first usage amount acquisition unit 131 (see step ST22) and the display part A by the measurement unit 132a. From the number of times of use for each C (see step ST21a), the total amount of use for each color of the display parts A to C is acquired (step ST24a).

  As described above in detail, in the second embodiment, the second usage amount acquisition unit 133a uses the color usage amounts for the display parts A to C by the first usage amount acquisition unit 131 and the measurement unit. The total usage amount for each color of the display parts A to C is acquired from the number of times of use for each of the display parts A to C by 132a.

  Thereby, the power consumption concerning a display can be minimized like 1st Embodiment. In addition, the load on the control unit 13 (CPU) can be reduced, and color assignment can be optimally performed with a small number of calculations.

(Third embodiment)
The third embodiment will be described focusing on differences from the previous embodiment.
FIG. 11 is a block diagram illustrating a configuration example of a control unit according to the third embodiment of the present invention.

  As illustrated in FIG. 11, the control unit 13b includes a first usage amount acquisition unit 131a, a measurement unit 132, a second usage amount acquisition unit 133b, an allocation unit 134a, and a display control unit 135.

  In the third embodiment, the color of the display parts P1 to P5 illustrated in FIG. 4 is assigned using the color map DAT2 stored in advance in the storage unit 14. At this time, the colors of the display parts P1 to P5 are not directly reassigned, but the colors of the items are reassigned in units of categories.

The above-described color map DAT2 will be described with reference to FIG.
FIG. 12 is a conceptual schematic diagram for explaining a color map according to the third embodiment of the present invention. FIG. 12 illustrates an enlarged display part P5 as a soft key illustrated in FIG.

  As illustrated in FIG. 12, the display part P <b> 5 as a soft key includes a frame F, a background B in the frame F, and characters in the frame F. Each component of such a display part is called an item. However, the display parts P2 and P3 representing the remaining battery level and the reception level shown in FIG. 4 do not necessarily require the frame F or characters when displayed as a single color image.

  The color map DAT2 in the storage unit 14 includes data related to the frame color of the frame F, the background color in the frame F, and the character color in the frame F. Furthermore, the frame color, background color, and character color have a standard color and a warning color. These colors are assigned according to the category.

  For example, in the first category used in the standard, white is assigned to the standard background color, yellow is assigned to the standard character color, and blue is assigned to the standard frame color. In the second category used for warning or the like, for example, when the remaining battery level or the reception level falls below a specified value, a warning color for warning that effect is assigned. For this reason, for example, red is assigned to the warning background color, purple is assigned to the warning character color, and black is assigned to the warning frame color.

  Hereinafter, the components of the control unit 13b different from the previous embodiment will be described. The 1st usage-amount acquisition part 131a acquires the usage-amount of a color for every item of display parts AC.

  The second usage amount acquisition unit 133b includes the usage amount of the color for each item in the display parts A to C by the first usage amount acquisition unit 131a and the usage time for each display part A to C by the measurement unit 132. The total usage amount by color for each item in the display parts A to C is acquired.

  A case where the second usage amount acquisition unit 133a acquires the total usage amount of the standard background color of each item in the display parts A to C will be described. The second usage amount acquisition unit 133a displays a value obtained by multiplying the usage amount of the standard background color in the display part A by the usage time, a value obtained by multiplying the usage amount of the background color in the display part B by the usage time, and a display. The sum total of the usage amount of the background color in the part C and the value obtained by multiplying the usage time is calculated. Similarly, the second usage amount acquisition unit 133a calculates the sum for the other colors.

  The allocation unit 134a determines the power consumption of the display unit 16 based on the total usage amount of each item by the second usage amount acquisition unit 133a and the power consumption data DAT1 and the color map DAT2 read from the storage unit 14. The color is reassigned to each item of the display parts A to C so as to be minimized.

  At this time, the assigning unit 134a sorts the colors used for the items of the display parts A to C in order from the color with the highest total usage amount to the lowest color. Then, the assigning unit 134a reassigns colors with low power consumption to the sorted colors.

  An operation related to the color arrangement function of the control unit 13b illustrated in FIG. 11 will be described. Also in the third embodiment, the update process and the allocation process are executed. However, since the update process is the same process as in the first embodiment, the description thereof will be omitted and only the assignment process will be described.

  FIG. 13 is a flowchart showing an operation example of assignment processing by the control unit according to the third embodiment of the present invention.

  As shown in FIG. 13, when the allocation process is started, the measuring unit 132 reads the usage time for each of the display parts A to C from the storage unit 14 (step ST21). And the 1st usage-amount acquisition part 131a acquires the usage-amount of a color for every item of display parts AC (step ST22a).

  Thereafter, allocation unit 134a reads power consumption data DAT1 and color map DAT2 from storage unit 14 (step ST23a). Then, the second usage amount acquisition unit 133b uses the color usage amount for each item in the display parts A to C by the first usage amount acquisition unit 131a (see step ST22a) and the display parts A to C by the measurement unit 132. From another use time (see step ST21), the total use amount for each color for each item in the display parts A to C is acquired (step ST24a).

  Thereafter, the assigning unit 134a uses the second usage amount acquisition unit 133a for the total usage amount of each item (see step ST24a), the power consumption data DAT1 and the color map DAT2 read from the storage unit 14 (see step ST23a). ), The colors of the display parts A to C are reassigned so that the power consumption of the display unit 16 is minimized (step ST25a).

  At this time, the assigning unit 134a sorts the colors used for the items of the display parts A to C in order from the color with the highest total usage amount to the lowest color. Then, the assigning unit 134a reassigns colors with low power consumption to the sorted colors.

  As described above in detail, in the third embodiment, since the color of each item is reassigned using the color map DAT2, the display screen can be displayed while maintaining the uniformity of the color arrangement of the display screen. Such power consumption can be minimized. In addition to this, it is possible to reduce the load on the control unit 13 (CPU) and optimally assign colors with a small number of calculations.

(Fourth embodiment)
A fourth embodiment will be described. In 3rd Embodiment, the measurement part 132a measures the usage time of a display part, and the 2nd usage-amount acquisition part 133b acquires the usage-amount of the color for every item based on this usage time. On the other hand, in the fourth embodiment, as in the second embodiment, the measuring unit 132a measures the number of times the display part is used, and the second usage amount acquiring unit 133b determines the number of times for each item based on the number of times of use. Get the color usage.

  Also in the fourth embodiment, it is possible to minimize the power consumption related to display while maintaining the uniformity of the color scheme of the display screen. In addition, the load on the control unit 13 (CPU) can be reduced, and color assignment can be optimally performed with a small number of calculations.

  In each of the above-described embodiments, when the remaining battery level is equal to or less than the specified value, the colors of the display parts can be reassigned regardless of the user's instruction. At this time, for example, a warning color may be assigned to the remaining battery capacity of the display unit 16. Thereby, not only can the power consumption of the display unit 16 be minimized to suppress a decrease in the remaining amount of the battery 18, but also the user can be prompted to charge the battery 18.

  The configuration of the control unit according to each embodiment described above shows an example of the processing procedure of the color arrangement function. In each embodiment, all the functions of each component of the control unit are processed in software, but some or all of the functions can be processed in hardware.

  The present invention can be applied not only to mobile terminals such as mobile phones and PHS, but also to various electronic devices such as desktop or notebook personal computers, PDAs (Personal Digital Assistants), and electronic dictionaries. For example, when the present invention is applied to a desktop personal computer, the display unit according to the present invention can be configured by a CRT (Cathode Ray Tube) display or the like.

It is a schematic block diagram which shows the structural example of the portable terminal which concerns on 1st Embodiment of this invention. It is a schematic cross section which shows the structural example of the display part at the time of comprising the display part which concerns on 1st Embodiment of this invention with a liquid crystal panel. It is a schematic cross section which shows the structural example of the display part at the time of comprising the display part which concerns on 1st Embodiment of this invention with the organic electroluminescent panel. It is a schematic diagram which shows the example of the display image of the display part which concerns on 1st Embodiment of this invention. It is a block diagram which shows the structural example of the control part which concerns on 1st Embodiment of this invention. It is a flowchart which shows the operation example of the update process by the control part which concerns on 1st Embodiment of this invention. It is a flowchart which shows the operation example of the allocation process by the control part which concerns on 1st Embodiment of this invention. It is a block diagram which shows the structural example of the control part which concerns on 2nd Embodiment of this invention. It is a flowchart which shows the operation example of the update process by the control part which concerns on 2nd Embodiment of this invention. It is a flowchart which shows the operation example of the allocation process by the control part which concerns on 2nd Embodiment of this invention. It is a block diagram which shows the structural example of the control part which concerns on 3rd Embodiment of this invention. It is a conceptual schematic diagram for demonstrating the color map which concerns on 3rd Embodiment of this invention. It is a flowchart which shows the operation example of the allocation process by the control part which concerns on 3rd Embodiment of this invention. It is a schematic block diagram which shows the structural example of a general portable terminal.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Portable terminal, 11 ... Antenna, 12 ... Communication part, 13 ... Control part, 14 ... Memory | storage part, 15 ... Voice input / output part, 15a ... Speaker, 15b ... Microphone, 16 ... Display part, 17 ... Operation part, 18 DESCRIPTION OF SYMBOLS ... Battery 19 ... Charging circuit 131 ... 1st usage-amount acquisition part 132 ... Measurement part 133 ... 2nd usage-amount acquisition part 134 ... Allocation part 135 ... Display control part 161 ... Glass substrate 162 ... transparent electrode, 163 ... polarizer, 164 ... glass substrate, 165 ... color filter, 166 ... transparent electrode, 167 ... polarizer, 168 ... liquid crystal, 169 ... backlight, 1610 ... light emitting layer, DAT1 ... power consumption data, DAT2 ... Color map, P1-P5 ... Display parts

Claims (8)

A display unit that displays at least one image and has different power consumption for each color to be displayed;
An acquisition unit that acquires, for each image, a usage amount for each color of the image displayed on the display unit;
A storage unit for storing a characteristic table indicating a relationship between the color of the image and the power consumption of the color;
An electronic device comprising: a control unit that sequentially replaces colors of an image acquired by the acquisition unit from colors having a larger usage amount to colors with lower power consumption based on the characteristic table, and displays the image on the display unit . The electronic device according to claim 1, wherein the image includes an image indicating an operation state of a predetermined function of the own device. The display unit displays a plurality of images,
The acquisition unit acquires the usage status for each image when updating the display of the display unit,
The controller is
The electronic device according to claim 2, wherein when an instruction to assign a color of the image to be displayed is received, a color with low power consumption of the display unit is assigned in order of an image with a large change in usage status. Based on the usage amount of each image for each color and the usage status of each image, the calculation unit for calculating the usage amount of the color occupied by all the images by color,
The acquisition unit
The electronic device according to claim 3, wherein an order of images having a large change in usage status is acquired from a calculation result by the calculation unit. The controller is
The color of an image to be assigned is determined from the order of colors associated with the power consumption of the display unit indicated by the characteristic table of the storage unit and the order of images having a large change in usage status by the acquisition unit. 4. The electronic device according to 4. The usage status of the image includes the usage time of the image,
Having a timekeeping unit for measuring the usage time of the image by image;
The calculation unit includes:
The electronic device according to claim 5, wherein, when calculating the usage amount for each color occupied by the image, the sum of the product of the usage amount of the color and the usage time of the image by the timing unit is calculated for each color. . The usage status of the image includes the number of times the image is used,
It has a measurement unit that measures the number of times the image is used for each image,
The calculation unit includes:
The electronic device according to claim 5, wherein, when calculating the usage amount for each color occupied by the image, the sum of the product of the usage amount of the color and the usage time of the image by the timing unit is calculated for each color. . Each of the images can be assigned a color for each part constituting the image,
The storage unit stores color arrangement data for performing color arrangement for each part of the image,
The controller is
The electronic device according to claim 6, wherein a color is assigned to each part of the image with reference to the color arrangement data in the storage unit.

Images