JP2007334034A - Portable electronic equipment, display control device, and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To attain compatibility of satisfactory screen display and reduction in electric power consumption. <P>SOLUTION: A display controller 200 for controlling the display operation of a display element 40 discriminates whether the kind of the image data inputted from a host controller 100 is an animation image or a static image. If the image kind is the animation image, the display controller 200 acquires the external light illuminance signal from an external light sensor 50, at the frame synchronizing signal on the verge of displaying the animation image. If, however, the image kind is a static image, the display controller acquires the external light illuminance signal at intervals longer than the timing, based on the frame synchronizing signal of the animation image; and the display controller 200 specifies the display luminance appropriate for the combination of the image luminance of that time and the external light illuminance, and controls the light quantity of the backlight 42 so as to attain the display luminance of that time. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a portable electronic device and a display control device, and more particularly to a portable electronic device and a display control device that realize good screen display and low power consumption.

  A portable electronic device such as a mobile communication terminal such as a cellular phone is provided with a display unit mainly composed of a liquid crystal display device and used for image display. In such portable electronic devices, various images can be displayed with high quality due to the development of image display technology. For example, in mobile communication terminals and the like, not only still images but also moving images (for example, taken images) can be displayed. Movie images, TV broadcasts, etc.) can also be displayed.

  In such a portable electronic device, since the place of use is not fixed, the environment for viewing the display image is not constant. In the case of a liquid crystal display device using a backlight that is employed in many portable electronic devices, the brightness of the surrounding environment affects the visibility of the display screen, and thus the visibility of the display image varies greatly depending on the usage environment. For example, even if it is possible to obtain good visibility at indoor brightness, in brighter places such as outdoors in fine weather, the reflection of external light on the display panel can affect the visibility of the displayed image. May be significantly reduced.

In order to eliminate such an inconvenience, a technique has been proposed in which the luminance around the display panel is detected and the luminance of the backlight is controlled based on the detected luminance (for example, Patent Document 1).
JP 2001-350134 A

  However, in the method of Patent Document 1, since the brightness of the backlight is uniformly adjusted regardless of the type of display image, the white portion tends to sink in a dark place, while the black portion tends to float in a bright place. Degradation of image quality occurs. For this reason, in the method of Patent Document 1, the contrast is increased by performing gamma correction processing according to the type of image. Since such additional processing is required, the method of Patent Document 1 increases the processing load during the display operation, increases the power consumption for the display operation, and may cause a decrease in display responsiveness. .

  In particular, since the display device is a portion with relatively high power consumption in the components of the portable electronic device, an increase in power consumption for the display operation greatly affects the power consumption of the entire device. In recent mobile communication terminals, etc., overall power consumption tends to increase due to multi-functionality, but longer battery drive time is also required, so improving display performance and reducing power consumption are effective. Establishment of a method that is compatible with each other is desired.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a portable electronic device or the like that achieves both good screen display and low power consumption.

In order to achieve the above object, a portable electronic device according to the first aspect of the present invention provides:
In a portable electronic device having a display device for displaying an image,
A sensor device for detecting ambient light illuminance;
Detection signal acquisition means for acquiring a detection signal of the sensor device;
Image discriminating means for discriminating the type of image displayed on the display device;
Image luminance detecting means for detecting the luminance of the image to be displayed;
Based on the detection signal acquired by the detection signal acquisition unit and the image luminance detected by the image luminance detection unit, the display luminance of the display device is controlled at a timing according to the image type determined by the image determination unit. Display control means for
It is characterized by providing.

In the portable electronic device,
When the image type determined by the image determining means is a moving image,
The detection signal acquisition unit and the display control unit operate at a timing based on a frame synchronization signal of the moving image,
When the image type determined by the image determining means is a still image,
It is desirable that the detection signal acquisition unit and the display control unit operate at a timing that is longer than an operation timing in the case of a moving image.

In order to achieve the above object, a display control apparatus according to the second aspect of the present invention provides:
A display control device for dimming a display device,
An external light illuminance detecting means for detecting the external light illuminance;
Image discriminating means for discriminating the type of image displayed on the display device;
Image luminance detecting means for detecting the luminance of the image to be displayed;
Based on the ambient light illuminance detected by the ambient light illuminance detection means and the image brightness detected by the image brightness detection means, the display brightness of the display device is controlled at a timing according to the image type determined by the image determination means. Dimming means,
It is characterized by providing.

In the display control device,
The dimming means preferably changes the control timing of the display luminance according to the image type determined by the image determining means.

In the display control device,
When the image type is a moving image, the dimming means desirably controls the display luminance at a timing based on a frame synchronization signal of the moving image.

In the display control device,
When the image type is a still image, it is preferable that the dimming unit controls the display luminance at a time interval longer than a control timing when a moving image is displayed.

In the display control device,
The outside light illuminance detection means includes
Sensor means for detecting ambient light illuminance;
It is desirable to further comprise signal conversion means for sampling the detection signal from the sensor means and converting it to a digital signal, in this case,
It is desirable that the signal conversion unit changes the sampling period of the sampling according to the image type determined by the image determination unit.

in this case,
When the image type is a moving image, the signal conversion unit preferably performs the sampling at a sampling period based on a frame synchronization signal of the moving image.

Also,
When the image type is a still image, the signal conversion unit preferably performs the sampling at a sampling cycle longer than a sampling cycle when a moving image is displayed.

In the display control device,
The display device can be a liquid crystal display device with a backlight, in this case,
It is desirable that the dimming unit controls the display luminance by controlling the light amount of the backlight.

  Furthermore, in order to achieve the above object, a program according to a third aspect of the present invention provides an external light illuminance detection procedure for detecting an external light illuminance to a computer that controls a display control device that performs dimming of the display device, and the display. An image determination procedure for determining the type of image to be displayed on the apparatus, an image brightness detection procedure for detecting the brightness of the image to be displayed, an external light illuminance detected by the external light illuminance detection means, and the image brightness detection means detected Based on the image brightness, a dimming procedure for controlling the display brightness of the display device at a timing according to the image type determined by the image determining means is realized.

  According to the present invention, the display luminance is controlled at a timing according to the image type, so that both good screen display and reduction in power consumption can be achieved.

  Hereinafter, embodiments according to the present invention will be described with reference to the drawings. In the present embodiment, a case where the portable electronic device according to the present invention is configured by a mobile communication terminal will be described. The mobile communication terminal 1 according to the present embodiment is a mobile communication terminal device (telephone) such as a mobile phone or a PHS (Personal Handyphone System), and in this embodiment, an image display function including a moving image is provided. It shall be equipped with.

  The configuration of such a mobile communication terminal 1 will be described with reference to FIG. FIG. 1 is a block diagram illustrating a configuration example of a mobile communication terminal 1 according to an embodiment of the present invention. As illustrated, the mobile communication terminal 1 according to the present embodiment includes a communication control unit 10, a camera unit 20, an operation unit 30, a display unit 40, an external light sensor 50, a storage unit 60, a host controller 100, and a display control unit. 200, and the like.

  The communication control unit 10 performs an operation related to a communication function that is a basic function of the mobile communication terminal 1. For example, communication using a communication method such as a CDMA (Code Division Multiple Access) method is used. A wireless communication is performed with a nearby base station by performing wireless transmission / reception by the antenna 11 that is configured by a device and is compatible with the communication method.

  The communication control unit 10 also includes a codec circuit that performs voice processing, for example, and performs voice processing related to voice calls. That is, the received voice data is converted into an analog signal and output from the speaker 12, and the transmission voice input from the microphone 13 is converted into digital data for transmission.

  The camera unit 20 is configured to realize the imaging function of the mobile communication terminal 1, and includes a lens on which subject light is incident, an imaging element that converts imaging light from the lens into an electrical signal (for example, a CCD (Charge Coupled) Device: charge-coupled device), ADC (Analog-Digital Converter) that converts an electrical signal from the imaging device into a digital signal, and the like. In the present embodiment, the imaging function of the camera unit 20 realizes a moving image imaging function for obtaining a moving image in addition to a still imaging function for obtaining a still image.

  The operation unit 30 includes, for example, a cross cursor key, an alphanumeric key for inputting numbers and characters, a key for specifying a function, and the like, and is operated by a user of the mobile communication terminal 1. . The operation unit 30 generates an input signal corresponding to the operation of these keys and inputs the input signal to the host controller 100.

  The display unit 40 has a configuration for realizing the image display function of the mobile communication terminal 1 and includes a display panel 41 and a backlight 42 as shown in FIG.

  The display panel 41 is a display panel configured from a general liquid crystal display (LCD) using the backlight 42 as a light source.

  The backlight 42 is a light source device configured by, for example, an LED (Light Emitting Diode) array and performs a light emitting operation as a light source necessary for display on the display panel 41. In the present embodiment, it is assumed that the light emission amount is variable according to the applied current.

  The external light sensor 50 is composed of, for example, an optical sensor, and detects the external light illuminance with respect to the mobile communication terminal 1. The external light sensor 50 is intended to detect the brightness of the surrounding environment that affects the visibility of the display image on the display unit 40. Therefore, it is assumed that the external light sensor 50 is disposed at a position where external light on the display surface of the display panel 41 can be detected. The external light sensor 50 performs a detection operation under the control of the display control unit 200 and sends a signal indicating the detected external light illuminance to the display control unit 200.

  The storage unit 60 includes, for example, a ROM (Read Only Memory), a flash memory, and the like, and stores data necessary for processing performed by the host controller 100 and the like, processing results by these, and the like. The storage unit 60 stores a program executed by the host controller 100. In the present embodiment, storage areas such as an image storage area 61 and a program storage area 62 are prepared as shown in FIG.

  The image storage area 61 stores image data constituting an image to be displayed on the display unit 40. The stored image data is, for example, image data generated by the camera unit 20 or image data acquired from the outside. This image data includes, for example, still image data such as a still photo image and moving image data such as a video image. When a memory card can be attached to the mobile communication terminal 1, the image storage area 61 may be configured in a removable memory card.

  The program storage area 62 stores an operation program executed by the host controller 100.

  The host controller 100 is composed of, for example, a CPU (Central Processing Unit), a RAM (Random Access Memory), and the like, and controls the operation of each unit of the mobile communication terminal 1. In the present embodiment, the host controller 100 executes the operation program stored in the program storage area 62, thereby realizing each process described below. The RAM configured in the host controller 100 is used as a work memory when the CPU executes a program.

  In the present embodiment, as shown in FIG. 1, the communication control unit 10, the camera unit 20, the operation unit 30, the storage unit 60, and the display control unit 200 described above are connected to the host controller 100, and the operation of the host controller 100 is performed. Controlled by.

  In the present embodiment, for example, the host controller performs an encoding process of an image obtained by an imaging operation of the camera unit 20 and a decoding process when displaying image data stored in the image storage area 61 on the display panel 41. 100 will do. Here, in encoding / decoding processing of a moving image, for example, a general encoding method such as an inter-frame prediction encoding method is used.

  Such an operation is performed, for example, by the host controller 100 when executing an application relating to the imaging function of the camera unit 20 or an application relating to image reproduction in accordance with an instruction from the user based on an input signal from the operation unit 30. It shall be realized.

  In the present embodiment, the operation related to such encoding / decoding processing and the like is realized by the host controller 100 executing a program. However, the present invention is not limited to this, and for example, an ASIC (Application Specific Integrated Circuit) : Processing may be performed by hardware such as a specific application integrated circuit).

  The display control unit 200 is configured to display an image by processing an output signal from the host controller 100 and controlling the display unit 40. The display control unit 200 according to the present embodiment has a configuration as shown in FIG.

  As illustrated, the display control unit 200 includes a host interface (I / F) 210, an operation control unit 220, a display memory 230, a memory write control unit 240, a memory read control unit 250, a panel drive unit 260, a backlight dimming. The unit 300 is configured.

  The host interface 210 is an interface that electrically connects the display control unit 200 and the host controller 100, and receives and inputs display target image data sent from the host controller 100.

  The operation control unit 220 includes, for example, a predetermined control circuit and the like, and controls each unit of the display control unit 200 based on the image data input from the host interface 210. Here, the operation control unit 220 determines whether the type of the image data acquired from the host controller 100 is still image data or moving image data, and each unit of the display control unit 200 according to the determined image type. To control. Here, the type of image data can be determined based on, for example, the header information of the acquired image data, and is determined based on, for example, the current operation mode, the type of application program being executed, and the like.

  The operation control unit 220 controls the backlight dimming unit 300 by setting different operation timings according to the determined image type. In the present embodiment, when a moving image is displayed (that is, when the determined image type is a moving image), a frame synchronization signal sent from the panel drive unit 260 is acquired, and back-up is performed at a timing based on the acquired frame synchronization signal. The light dimmer 300 is controlled. When still images are displayed (that is, when the determined image type is a still image), at least a timing (for example, 1 second to several seconds) that is longer than the operation timing based on the frame synchronization signal at the time of moving image display. The backlight dimming unit 300 is controlled at intervals.

  In this embodiment, the case where the operation control unit 220 is configured by a dedicated circuit is illustrated, but the present invention is not limited to this. For example, the function of the operation control unit 220 is realized by software processing when the host controller 100 executes a program. You may comprise.

  The display memory 230 is a memory (so-called VRAM (Video RAM)) for expanding image data to be displayed on the display panel 41. As shown in FIG. 2, the display memory 230 according to the present embodiment has a moving image expansion area 231 for expanding moving image data and a still image expansion area 232 for expanding still image data. .

  In the present embodiment, the moving image expansion area 231 and the still image expansion area 232 are logically defined based on the address on the display memory 230. However, the moving image expansion area 231 and the still image expansion area 232 May be composed of physically different storage devices (storage elements).

  The memory write control unit 240 controls writing (development) of image data to the display memory 230. In this case, the memory write control unit 240 develops the image data acquired from the host interface 210 in the moving image development region 231 or the still image development region 232 under the control of the operation control unit 220. That is, if the acquired image data is moving image data, it is expanded in the moving image expansion area 231, and if it is still image data, it is expanded in the still image expansion area 232.

  The memory read control unit 250 controls reading (output) of image data from the display memory 230. In this case, the memory read control unit 250 reads the image data developed in the moving image development region 231 or the still image development region 232 under the control of the operation control unit 220. That is, if the image data to be displayed is moving image data, the image data expanded in the moving image expansion area 231 is read, and if it is still image data, the image data expanded in the still image expansion area 232 is read.

  For the display refresh of the display panel 41, the memory read control unit 250 reads out image data from the display memory 230 at 60 Hz, for example, and sends it to the panel drive unit 260 and the backlight dimming unit 300.

  The panel drive unit 260 performs processing for displaying the image data read by the memory read control unit 250 on the display panel 41. The panel driving unit 260 includes, for example, a segment driver for driving the data electrodes of the liquid crystal panel (display panel 41), a common driver for driving the scanning electrodes, and the like, and the input image data is driven by the liquid crystal panel. By converting the voltage into a voltage and supplying it to the display panel 41, an image is displayed on the display panel 41.

  Further, the panel drive unit 260 sends a frame synchronization signal related to moving image display on the display panel 41 to the operation control unit 220. In this case, when the moving image data is displayed, the panel driving unit 260 generates a frame synchronization signal at the frame switching timing and sends it to the operation control unit 220. In this case, for example, the frame synchronization signal is generated at a time interval corresponding to the frame rate of the moving image (for example, 30 fps or 60 fps) (for example, approximately every 1/60 to 1/30 seconds).

  The backlight dimming unit 300 controls the amount of light of the backlight 42 according to the type of image (still image or moving image) to be displayed on the display panel 41, and adjusts the display brightness on the display panel 41. It is the structure for controlling. The configuration of the backlight dimming unit 300 will be described with reference to FIG.

  FIG. 3 is a block diagram illustrating a configuration of the backlight dimming unit 300. As illustrated, the backlight dimming unit 300 includes a sensor signal conversion unit 310, a luminance component extraction unit 320, an average luminance calculation unit 330, a display luminance setting unit 340, a setting storage unit 350, a light source driver 360, and the like. The

  The sensor signal conversion unit 310 is configured by, for example, an ADC (Analog-Digital Converter) and acquires a detection signal (sensor signal) transmitted from the external light sensor 50 and converts it into a digital signal. . In this case, the sensor signal conversion unit 310 samples the analog signal transmitted by the external light sensor 50 at a predetermined sampling period and converts it into a digital signal.

  The sensor signal conversion unit 310 operates under the control of the operation control unit 220. As described above, since the operation control unit 220 controls the sensor signal conversion unit 310 at a timing according to the determined image type, the sensor signal conversion unit 310 operates at a timing according to the image type. That is, when the image type determined by the operation control unit 220 is a moving image, the operation is performed at a frame switching timing for displaying the moving image, and when the image type is a still image, a predetermined timing (for example, 1 to every few seconds).

  In this case, the sensor signal conversion unit 310 acquires and samples the detection signal from the external light sensor 50 at the control timing of the operation control unit 220. That is, sampling is performed with the control timing by the operation control unit 220 as the sampling period. The sensor signal conversion unit 310 sends the digital signal converted by sampling in such a sampling period to the display luminance setting unit 340. That is, a digital signal indicating the external light illuminance is supplied to the display luminance setting unit 340 at a timing according to the image type determined by the operation control unit 220.

  The luminance component extraction unit 320 includes, for example, a predetermined arithmetic circuit and extracts the luminance component of the display target image sent from the memory read control unit 250. This luminance component extraction uses a general method used in the existing image processing technology. Here, if the image supplied from the memory read control unit 250 is a still image, the luminance component of the image is extracted. If the image is a moving image, the luminance component is extracted for each frame image of the moving image. Shall.

  The average luminance calculation unit 330 includes, for example, a predetermined arithmetic circuit, calculates an average value of luminance components extracted by the luminance component extraction unit 320, and sends a signal indicating the calculated value to the display luminance setting unit 340. .

  The display luminance setting unit 340 includes, for example, a predetermined arithmetic circuit and the like, acquires information indicating the illuminance of outside light from the sensor signal conversion unit 310, and acquires information indicating the image luminance from the average luminance calculation unit 330. Then, based on the acquired information, the display brightness suitable for the combination of the ambient light illuminance and the image brightness at that time is specified, and the operating current of the backlight 42 for setting the specified display brightness is set. Here, since the sensor signal conversion unit 310 performs sampling at the operation timing based on the control from the operation control unit 220, the display luminance setting unit 340 indicates the information indicating the external light illuminance at the timing according to the image type to be displayed. Will get.

  In the present embodiment, it is assumed that the display luminance setting unit 340 operates at the timing when information indicating the external light illuminance is acquired from the sensor signal conversion unit 310. Therefore, the display brightness setting unit 340 sets the operating current of the backlight 42 at a timing according to the image type. In the present embodiment, by referring to the setting information stored in the setting storage unit 350, the operating current of the backlight 42 having a suitable display luminance is set, and information indicating the set operating current value is set as the light source driver 360. To send.

  The setting storage unit 350 is composed of, for example, a semiconductor storage device, and stores setting information referred to when the display luminance setting unit 340 sets the operating current of the backlight 42. An example of setting information stored in the setting storage unit 350 will be described with reference to FIG.

  FIG. 4A shows an example of an “external light level correspondence table” in which a value of external light illuminance detected by the external light sensor 50 is associated with a predetermined level. In the present embodiment, it is assumed that the level is set in advance by dividing the detected value of the ambient light illuminance in units of a predetermined range. In the external light level correspondence table shown in FIG. 4A, five levels (hereinafter referred to as “external light level”) of 1 to 5 are set in the order of low (ie, dark) external light illuminance value. Shall.

  FIG. 4B shows an example of an “image luminance level correspondence table” in which the luminance value (luminance component) of the display image calculated by the average luminance calculator 330 is associated with a predetermined level. In the present embodiment, it is assumed that the calculated image brightness value (for example, 0 to 255) is divided and set in units of a predetermined range. In the image luminance level correspondence table shown in FIG. 4B, five levels (hereinafter referred to as “image luminance levels”) of 1 to 5 are set in order of decreasing image luminance values (that is, dark). To do.

  FIG. 4C shows an example of a “display brightness level correspondence table” in which combinations of external light levels and image brightness levels are associated with display brightness levels and operating current values. In the present embodiment, for example, based on the display performance of the display panel 41, the light emission performance of the backlight 42, and the like, a suitable display brightness level corresponding to the combination of the external light illuminance and the image brightness at the time of image display is set in advance. Suppose that it is set in the display luminance level correspondence table. In this embodiment, it is assumed that five levels (hereinafter referred to as “display luminance levels”) of 1 to 5 are set in order of dark display luminance, and each display luminance is set as shown in FIG. The level value is associated with the operating current value of the backlight 42 which is necessary for causing the backlight 42 to emit light with a light amount that becomes the display luminance level.

  That is, the display luminance setting unit 340 refers to the external light illuminance level correspondence table and the image luminance level correspondence table, so that the external light illuminance value acquired from the sensor signal conversion unit 310 and the image luminance value acquired from the average luminance calculation unit 330 are calculated. The level corresponding to each can be specified, and by referring to the display luminance level correspondence table, the display luminance level corresponding to the combination of the specified ambient light illuminance and the image luminance level and the operating current value therefor can be obtained. Can be identified. The display brightness setting unit 340 sends information indicating the operating current value specified in this way to the light source driver 360.

  The light source driver 360 is a driver device that drives and controls the backlight 42, and controls the light emission operation of the backlight 42 based on information indicating the operating current value supplied from the display luminance setting unit 340. That is, by applying a current having an operating current value set by the display brightness setting unit 340 to the backlight 42, the backlight 42 emits a light amount corresponding to the set display brightness.

  In the present embodiment, the luminance component extraction unit 320, the average luminance calculation unit 330, and the display luminance setting unit 340 are configured by hardware such as an arithmetic circuit. However, the present invention is not limited to this. For example, a host controller These functions may be realized by software processing when the program 100 executes the program.

  In addition, the setting storage unit 350 can be configured from a dedicated storage device, or may be configured in the storage unit 60, for example. When the setting information stored in the setting storage unit 350 is fixed information set in advance based on the performance of the display panel 41 or the backlight 42, the setting storage unit 350 is stored in a non-rewritable storage device such as a ROM. It may be configured. However, for example, the information recorded in the display brightness level correspondence table may be changed according to the user's preference and the like. In this case, the setting storage unit 350 uses a rewritable storage device (flash memory or the like). Desirably configured.

  Each of the above-described configurations is a configuration necessary for realizing the present invention, and other configurations necessary for a basic function and an additional function as a mobile communication terminal are provided as necessary.

  The operation of the mobile communication terminal 1 having such a configuration will be described below. Here, an image display process executed by the display control unit 200 when image data is sent from the host controller 100 to the display control unit 200 will be described with reference to a flowchart shown in FIG. This image display process is started when image data is input from the host controller 100 to the display control unit 200.

  When the process is started, the operation control unit 220 determines the type (image type) of the input image data (step S101). Here, it is determined whether the input image is a moving image or a still image.

  When the image type is determined, the operation control unit 220 notifies the determined image type to the memory write control unit 240 and the memory read control unit 250.

  Based on the notification from the operation control unit 220, the memory write control unit 240 develops the image data supplied from the host interface 210 in either the moving image development region 231 or the still image development region 232 (step S102). . That is, if the image type is a moving image, the data of each supplied frame image is expanded in the moving image expansion area 231, and if the image type is a still image, the supplied image data is expanded in the still image expansion area 232.

  In response to the notification from the operation control unit 220, the memory read control unit 250 reads the developed image data from either the moving image development region 231 or the still image development region 232 (step S103), and performs panel driving. To the unit 260 and the backlight dimming unit 300. Here, if the notified image type is a moving image, the image data expanded in the moving image expansion area 231 is read out, and if it is a still image, the image data expanded in the still image expansion area 232 is read out.

  The panel drive unit 260 drives and controls the display panel 41 based on the image data supplied from the memory read control unit 250, and displays the image on the display panel 41 (step S104).

  Here, when the display image is a moving image, the panel drive unit 260 generates a frame synchronization signal for displaying the moving image (step S105) and sends it to the operation control unit 220 as needed.

  In parallel with the processes in steps S102 to S105, a backlight emission process for causing the backlight 42 to emit light is executed by the operation control unit 220 and the backlight dimming unit 300 (step S200). The backlight emission process is started when the operation control unit 220 determines the image type. The backlight emission process will be described with reference to the flowchart shown in FIG.

  When the backlight emission process is started, the operation control unit 220 instructs the sensor signal conversion unit 310 to execute the operation. Based on this instruction, the sensor signal conversion unit 310 converts the sensor signal indicating the ambient light illuminance acquired from the ambient light sensor 50 into a digital signal. Here, the sensor signal conversion unit 310 converts the sensor signal indicating the external light illuminance value detected by the external light sensor 50 into a digital signal (hereinafter referred to as an “external light illuminance signal”) at a timing when an instruction is received from the operation control unit 220. And sent to the display brightness setting unit 340. Thereby, an external light illuminance signal is acquired at an instruction timing by the operation control unit 220 (step S201).

  When the display luminance setting unit 340 acquires the external light illuminance signal sent from the sensor signal conversion unit 310, the display luminance setting unit 340 refers to the external light level correspondence table (FIG. 4A) of the setting storage unit 350 and corresponds to the current external light illuminance. The ambient light level is specified (step S202).

  Here, when the image data developed in the display memory 230 is input to the backlight dimming unit 300 by the operation of the memory read control unit 250 in step S103, the luminance component extraction unit 320 causes the luminance of the image to be displayed. The components are extracted (step S203), and the average luminance calculation unit 330 calculates the average luminance (step S204) and supplies it to the display luminance setting unit 340.

  When the display luminance setting unit 340 acquires the average luminance value calculated by the average luminance calculation unit 330, the display luminance setting unit 340 refers to the image luminance level correspondence table (FIG. 4B) in the setting storage unit 350 and corresponds to the luminance of the image to be displayed. The image luminance level to be specified is specified (step S205).

  The display luminance setting unit 340 further refers to the display luminance level correspondence table (FIG. 4C) in the setting storage unit 350 and corresponds to the combination of the external light level specified in step S202 and the image luminance level specified in step S205. The operating current value to be determined is specified (step S206) and notified to the light source driver 360.

  The light source driver 360 drives and controls the backlight 42 with the operating current value notified from the display luminance setting unit 340 (step S207). As a result, the backlight 42 emits light with a light quantity that provides a suitable display brightness obtained based on the brightness of the image to be displayed and the illuminance of outside light, and the flow returns to the flow of the image display process shown in FIG.

  In the image display process, the operation control unit 220 determines whether or not to end the image display operation (step S106). Here, for example, it is determined whether or not to end the image display operation based on the supply state of the image data from the host controller 100 to the display control unit 200 or an instruction from the host controller 100.

  When the image display operation is not finished (step S106: No), the process returns to step S102 to continue the image display on the display panel 41 and to control the display brightness by the dimming of the backlight 42. Is executed in parallel with the image display operation by the operation control unit 220 and the backlight dimming unit 300 (step S300). This display brightness control process will be described with reference to the flowchart shown in FIG.

  Here, when the image type determined in step S101 is a moving image (step S301: Yes), the operation control unit 220 generates a frame synchronization signal in the panel drive unit 260 (step S302: Yes), and the timing thereof. The sensor signal conversion unit 310 is instructed to execute the operation (step S303). In this case, the backlight dimming unit 300 performs the same operations as those in the above-described backlight emission process (FIG. 6: steps S201 to S207) (step S200).

  That is, the sensor signal conversion unit 310 sends an external light illuminance signal to the display luminance setting unit 340 at the instruction timing from the operation control unit 220 in step S303. The display luminance setting unit 340 specifies a suitable display luminance by specifying the external light level and the image luminance level at the timing when the external light illuminance signal is acquired. Then, by operating the backlight 42 with the operating current value that provides the specified display brightness, the amount of light of the backlight 42 is adjusted, and screen display is performed with a suitable display brightness.

  Then, the flow returns to the image display processing flow shown in FIG. Here, until the end of the image display operation is determined (step S106: Yes), the display luminance control process (step S300) is repeatedly executed (step S106: No). That is, when the image type is a moving image, the display luminance is adjusted at the timing each time a frame synchronization signal is generated. In this case, since the digital conversion by the sensor signal conversion unit 310 is performed at the timing, in other words, the detection signal of the ambient light illuminance is sampled and acquired at the sampling period based on the frame synchronization signal.

  By operating in this way, the display brightness is dynamically adjusted according to the image brightness and the external light illuminance of each frame image constituting the moving image, and a good screen display can be obtained.

  Here, returning to the above-described display luminance control processing flow of FIG. 7, the operation when the image type is a still image (step S301: No) will be described. In this case, the operation control unit 220 has at least a predetermined time that is a time interval (for example, every 1 to several seconds) longer than a time interval (for example, every 1/60 to 1/30 seconds) based on the frame synchronization signal. (Step S305: Yes), the sensor signal conversion unit 310 is instructed to execute an operation at that timing (step S303). Also in this case, the backlight dimming unit 300 performs the same operation as the operation of the backlight emission process (FIG. 6: steps S201 to S207) shown in FIG. 6 (step S200).

  As in the case of the moving image described above, the display luminance control process (step S300) is repeatedly executed until the end of the image display operation is determined in the image display process (FIG. 5) (step S106: Yes). (Step S106: No). That is, when the image type is a still image, the display brightness is adjusted at a timing that is longer than the operation timing based on the frame synchronization signal at the time of moving image display.

  As described above, the display control unit 200 displays an image while dynamically adjusting the display luminance. Then, when the operation control unit 220 determines the end of the image display operation in the image display process (FIG. 5) (step S106: Yes), the display control unit 200 ends the image display process.

  With the above operation, when displaying a moving image, the display luminance is adjusted at the timing based on the frame synchronization signal generated at the display switching timing of the frame image, so that the image luminance can be changed for each frame image. Even when a moving image is displayed, it can always be displayed with a suitable display luminance.

  On the other hand, when displaying a still image with no change in image brightness, display brightness adjustment is performed at a time interval that is at least longer than when moving images are displayed, so the number of operations for display brightness adjustment is less than when moving images are displayed. . For this reason, it is possible to display an image with less power consumption than when displaying a moving image. Even in this case, since the display brightness is adjusted every predetermined time, for example, even if the external light illuminance changes as the mobile communication terminal 1 moves, the display brightness according to the external light illuminance at that time Therefore, a good screen display can be obtained.

  As described above, by applying the present invention as in the above embodiment, the display brightness is adjusted by changing the operation timing according to the type of image to be displayed, so that a good screen display and power consumption can be reduced. Both can be achieved.

  The said embodiment is an example and the application range of this invention is not restricted to this. That is, various applications are possible, and all embodiments are included in the scope of the present invention.

  In the above embodiment, the frame synchronization signal is generated at the display switching timing of each frame image at the time of moving image display. However, the present invention is not limited to this. For example, the frame synchronization signal is generated when the change in image luminance is large. May be.

  For example, when an inter-frame differential encoding method is used for encoding a moving image, inter-frame differential encoding is performed for a frame with little change from the previous frame, and the change from the first frame or the previous frame is performed. Intra coding is performed on frames with a large. In such a case, the display brightness adjustment can be performed at the timing when the frame having a large change in image brightness is displayed by generating the frame synchronization signal at the timing when the frame subjected to the intra coding is displayed. In other words, it can be said that the change in image brightness is small in the portion where the image change between frames is small, so that the display brightness adjustment is not performed while the frame subjected to the inter-frame difference encoding is displayed. Power consumption can be reduced even during display.

  In the above embodiment, the display brightness is adjusted every predetermined time when displaying a still image. However, in the case of a still image, there is no change in the image brightness. This is a case where a change occurs in the light illuminance. Therefore, the sensor signal conversion unit 310 or the like constantly monitors the detection value of the external light illuminance by the external light sensor 50. For example, when a change that exceeds a predetermined threshold appears in the detection value, the sensor signal indicating the detection value May be converted to digital and supplied to the display luminance setting unit 340, and the display luminance may be adjusted at that timing.

  In the above embodiment, the case where the present invention is applied to a mobile communication terminal is illustrated. However, as long as a display device capable of adjusting display luminance is provided, the present invention is not limited to a mobile communication terminal, and various The present invention can be applied to portable electronic devices (for example, PDAs (Personal Digital Assistants), digital cameras, personal computers, etc.).

  In the above embodiment, a liquid crystal display device using a backlight is exemplified, but the present invention is not limited to this as long as the display luminance can be adjusted, and the present invention can be applied to any display device.

Furthermore, the configuration of each control unit and the like according to the above embodiment may be realized by software processing of the host controller 100 or another control unit as well as being realizable by hardware. In this case, a program for realizing each process described above may be stored in the storage unit 60, and the host controller 100 may execute such a program.
And it can be made to function as the mobile communication terminal 1 concerning the said embodiment not only that it can provide as a display control apparatus with such a program incorporated previously.
The method of providing such a program is arbitrary. For example, the program may be provided via a communication medium such as the Internet, or may be distributed by being stored in a recording medium such as a memory card.

It is a block diagram which shows the structure of the mobile communication terminal concerning embodiment of this invention. It is a block diagram which shows the structure of the display control part shown in FIG. It is a block diagram which shows the structure of the backlight light control part shown in FIG. FIG. 4 is a diagram illustrating an example of information stored in a setting storage unit illustrated in FIG. 3, where (a) illustrates an example of an external light level correspondence table, (b) illustrates an example of an image luminance level correspondence table, and (c) ) Shows an example of a display luminance level correspondence table. It is a flowchart for demonstrating the image display process concerning embodiment of this invention. 6 is a flowchart for explaining a backlight emission process executed in the image display process shown in FIG. 5. It is a flowchart for demonstrating the display brightness control process performed by the image display process shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Mobile communication terminal, 10 ... Communication control part, 11 ... Antenna, 12 ... Speaker, 13 ... Microphone, 20 ... Camera part, 30 ... Operation part, 40 ... Display part, 41 ... Display panel, 42 ... Back light, DESCRIPTION OF SYMBOLS 50 ... External light sensor, 60 ... Memory | storage part, 61 ... Image storage area, 62 ... Program storage area, 100 ... Host controller, 200 ... Display control part, 210 ... Host interface, 220 ... Operation control part, 230 ... Display memory, 231 ... Moving image development area, 232 ... Still image development area, 240 ... Memory write control section, 250 ... Memory read control section, 260 ... Panel drive section, 300 ... Backlight dimming section, 310 ... Sensor signal conversion section, 320 ... luminance component extraction unit, 330 ... average luminance calculation unit, 340 ... display luminance setting unit, 350 ... setting storage unit, 360 ... light source driver

Claims (11)

In a portable electronic device having a display device for displaying an image,
A sensor device for detecting ambient light illuminance;
Detection signal acquisition means for acquiring a detection signal of the sensor device;
Image discriminating means for discriminating the type of image displayed on the display device;
Image luminance detecting means for detecting the luminance of the image to be displayed;
Based on the detection signal acquired by the detection signal acquisition unit and the image luminance detected by the image luminance detection unit, the display luminance of the display device is controlled at a timing according to the image type determined by the image determination unit. Display control means for
A portable electronic device comprising: When the image type determined by the image determining means is a moving image,
The detection signal acquisition unit and the display control unit operate at a timing based on a frame synchronization signal of the moving image,
When the image type determined by the image determining means is a still image,
The detection signal acquisition unit and the display control unit operate at a timing that is longer than the operation timing in the case of a moving image.
The portable electronic device according to claim 1. A display control device for dimming a display device,
An external light illuminance detecting means for detecting the external light illuminance;
Image discriminating means for discriminating the type of image displayed on the display device;
Image luminance detecting means for detecting the luminance of the image to be displayed;
Based on the ambient light illuminance detected by the ambient light illuminance detection means and the image brightness detected by the image brightness detection means, the display brightness of the display device is controlled at a timing according to the image type determined by the image determination means. Dimming means,
A display control apparatus comprising: The dimming means changes the control timing of the display luminance according to the image type determined by the image determining means.
The display control apparatus according to claim 3. When the image type is a moving image, the dimming unit controls the display luminance at a timing based on a frame synchronization signal of the moving image.
The display control apparatus according to claim 4. When the image type is a still image, the dimming means controls the display luminance at a time interval longer than a control timing when a moving image is displayed.
The display control apparatus according to claim 4, wherein: The outside light illuminance detection means includes
Sensor means for detecting ambient light illuminance;
Signal conversion means for sampling a detection signal from the sensor means and converting it into a digital signal; and
The signal conversion unit changes the sampling period of the sampling according to the image type determined by the image determination unit.
The display control apparatus according to claim 3, wherein the display control apparatus is a display control apparatus. When the image type is a moving image, the signal conversion means performs the sampling at a sampling period based on a frame synchronization signal of the moving image.
The display control apparatus according to claim 7. When the image type is a still image, the signal conversion unit performs the sampling at a sampling cycle longer than a sampling cycle when displaying a moving image.
The display control apparatus according to claim 7, wherein the display control apparatus is a display control apparatus. The display device is a liquid crystal display device provided with a backlight,
The dimming means controls the display brightness by controlling the amount of light of the backlight.
The display control apparatus according to claim 3, wherein the display control apparatus is a display control apparatus. In a computer that controls a display control device that performs dimming of the display device,
An ambient light illuminance detection procedure for detecting ambient light illuminance;
An image determination procedure for determining the type of image to be displayed on the display device;
An image luminance detection procedure for detecting the luminance of the image to be displayed;
Based on the ambient light illuminance detected by the ambient light illuminance detection means and the image brightness detected by the image brightness detection means, the display brightness of the display device is controlled at a timing according to the image type determined by the image determination means. Dimming procedure to
A program characterized by realizing.

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