JP2013037140A - Electronic apparatus, and luminance control program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce luminance differences between a plurality of display screens and to improve visibility of the display screens.SOLUTION: A portable terminal 10 includes an illuminance sensor 11, a processor 12 and a plurality of LCD units 151a and 152a. The processor 12 acquires an illuminance from the illuminance sensor 11. The processor 12 acquires luminance setting values of the LCD units 151a and 152a respectively, from a setting value reference table 131 in which the illuminance, the luminance setting value of the LCD unit 151a and the luminance setting value of the LCD unit 152a are associated with each other and stored. The processor 12 notifies the LCD unit 151a of the acquired luminance setting value of the LCD unit 151a, and notifies the LCD unit 152a of the acquired luminance setting value of the LCD unit 152a.

Description

  The present invention relates to an electronic device and a brightness control program.

  2. Description of the Related Art Conventionally, along with the development of display control technology, a portable terminal device that uses an illuminance sensor to control the luminance of a display screen according to the ambient illuminance has been proposed. Normally, LCD (Liquid Crystal Display) screens used in portable terminal devices are darker to the user as the surroundings become brighter, and the display image becomes difficult to see. Is adjusted so as to increase the brightness. Thereby, the user of the portable terminal device can visually recognize characters and images through an easy-to-see screen regardless of the surrounding environment. In recent years, a portable terminal device in which a plurality of display devices each having the above-described illuminance sensor are combined has also been proposed. Such portable terminal devices display not only different characters and images on each of a plurality of display screens (multi-screens), but also display one character or image on a plurality of display screens.

JP-A-5-88655

  However, the above-described technique has the following problems. For example, when the user hides the portion of the illuminance sensor with a finger or the sensitivity of the sensor decreases depending on the angle held, a difference may occur in the detected illuminance of the illuminance sensor corresponding to each display screen. In addition, since the illuminance sensors on each display screen operate independently from each other, the timing at which each sensor detects ambient illuminance may deviate even when sensors of the same specification are used. In this case, the luminance is adjusted only for one display device, and the luminance is not adjusted for the other display device. Furthermore, in one portable terminal device, a plurality of LCDs having different luminance specifications may be used in combination.

  Due to the above factors, in one portable terminal device, one display device displays a screen with high brightness (brighter), and the other display device displays a screen with low brightness (darker). Sometimes. As a result, the display screen of the portable terminal device has a reduced visibility and is difficult for the user to see. Although these inconveniences may occur when different characters and images are displayed on each display screen, they are particularly noticeable when one character or image is displayed on a plurality of display screens of one portable terminal device. Met.

  The disclosed technology has been made in view of the above, and an object thereof is to provide an electronic device and a luminance control program that reduce luminance differences among a plurality of display screens and improve the visibility of the display screens. To do.

  In order to solve the above-described problems and achieve the object, an electronic device disclosed in the present application includes, in one aspect, an illuminance sensor, a processor, and a plurality of display units. The processor acquires illuminance from the illuminance sensor. The processor displays a first display corresponding to the illuminance acquired from a table in which the illuminance, the luminance setting value of the first display unit, and the luminance setting value of the second display unit are stored in association with each other. The brightness setting value of the part and the brightness setting value of the second display part are acquired. The processor notifies the first display unit of the acquired luminance setting value of the first display unit and notifies the second display unit of the acquired luminance setting value of the second display unit. .

  According to one aspect of the electronic device disclosed in the present application, it is possible to reduce the luminance difference among a plurality of display screens and improve the visibility of the display screens.

FIG. 1A is an external perspective view of a portable terminal in a closed state. FIG. 1B is an external perspective view of the portable terminal in an opened state. FIG. 2 is a diagram illustrating a hardware configuration of the portable terminal. FIG. 3 is a diagram illustrating an example of data storage in the set value reference table. FIG. 4 is a diagram for explaining the operation of the portable terminal. FIG. 5 is a diagram for explaining processing executed by the processor. FIG. 6A is a diagram showing an example of a display screen before the LCD luminance difference is reduced. FIG. 6B is a diagram illustrating an example of the display screen after the LCD luminance difference is reduced. FIG. 7 is a diagram illustrating a computer that executes a brightness control program.

  Embodiments of an electronic apparatus and a brightness control program disclosed in the present application will be described below in detail with reference to the drawings. The electronic device and the brightness control program disclosed in the present application are not limited by the following embodiments.

  Hereinafter, embodiments of a portable terminal as an electronic device disclosed in the present application will be described with reference to the drawings. FIG. 1A is an external perspective view of the portable terminal 10 in a closed state. The portable terminal 10 can be opened and closed by the hinge 10a. By opening the hinge 10a as a rotation axis, the portable terminal 10 changes from the state shown in FIG. 1A to the state shown in FIG. 1B. FIG. 1B is an external perspective view of the portable terminal 10 in an open state. As shown in FIG. 1B, the portable terminal 10 has an LCD unit 151a that can be visually recognized by the user on the front surface, and an opening 11a on the upper left portion on the same surface. The portable terminal 10 includes an illuminance sensor 11 for detecting the illuminance around the terminal from the amount of light incident on the opening 11a from the surroundings. Note that the arrangement of the opening 11a and the illuminance sensor 11 is not limited to the upper left part of the front surface, but is necessarily required to be on the same plane as the LCD unit 151a as long as the illuminance around the terminal can be detected with a predetermined accuracy. do not do.

  The portable terminal 10 has two LCD units 151a and 152a. These two LCD units 151a and 152a are arranged in a spread state so that the user can view them simultaneously. The LCD units 151a and 152a can display different characters and images independently. However, since these screens have the same size and shape, one character or image is displayed as one screen. You can also As described above, the portable terminal 10 has one opening 11a and one illuminance sensor 11 in the upper left part of the front surface. Therefore, the opening 11a and the illuminance sensor 11 are arranged on the same surface as the LCD unit 151a, but the opening and the illuminance sensor are not arranged on the same surface as the LCD unit 152a.

  FIG. 2 is a diagram illustrating a hardware configuration of the portable terminal 10. As shown in FIG. 2, the portable terminal 10 includes an illuminance sensor 11, a processor 12, a memory 13, and LCD units 151a and 152a. Furthermore, the LCD units 151a and 152a have backlights 151 and 152, respectively, and backlight control ICs (Integrated Circuits) 141 and 142 for controlling the luminance of the backlights 151 and 152, respectively. Each of these components is connected so that signals and data can be input and output in one direction or in both directions.

The illuminance sensor 11 includes a PIN photodiode having a light receiving element capable of generating a current corresponding to the amount of incident light, and is an optical sensor that detects the intensity of light from various light sources such as sunlight and fluorescent lamps. The illuminance sensor 11 detects the illuminance around the portable terminal 10 and outputs the detection result to the processor 12. Here, the illuminance is the intensity of light entering the object (sensor), and generally, the illuminance of the display screen is appropriately about 500 [lx] or less. Luminance is the intensity of light coming out of an object (screen). In general, the luminance of a display screen is about 100 to 200 [cd / m ² ].

  The processor 12 is, for example, an integrated circuit such as an application specific integrated circuit (ASIC) or a field programmable gate array (FPGA), or an electronic circuit such as a central processing unit (CPU) or a micro processing unit (MPU). The processor 12 executes a control program such as an OS (Operating System) and a device driver. For example, the processor 12 monitors the presence or absence of notification of the illuminance detection result from the illuminance sensor 11. When the processor 12 receives the notification of the illuminance detection result from the illuminance sensor 11, the processor 12 acquires a setting value from the memory 13 based on the illuminance detection result, and uses the setting value as the LCD luminance setting value. 142, and the brightness of each LCD unit 151a, 152a is adjusted.

  The memory 13 is, for example, a semiconductor memory device such as a RAM (Random Access Memory), a ROM (Read Only Memory), or a flash memory, or a storage device such as a hard disk or an optical disk. When the memory 13 receives a setting value read request from the processor 12, the memory 13 reads the setting value corresponding to the illuminance and responds to the processor 12 with the setting value.

The memory 13 has a set value reference table 131 for determining a set value from the illuminance. FIG. 3 is a diagram illustrating an example of data storage in the set value reference table 131. As shown in FIG. 3, in the setting value reference table 131, the setting value of each LCD unit 151a, 152a includes the ambient illuminance and the LCD unit luminance so that the setting value of each screen can be determined as the illuminance is detected. Are stored in association with each other. The ambient illuminance is a value read by the illuminance sensor 11, and a value of 0 to 5000 [lx] is stored in ascending order. Further, the LCD unit luminance is associated with the illuminance so that the LCD unit luminance increases as the illuminance increases. The LCD unit brightness is, for example, 35 [cd / m ² ] when the illuminance is 0 to 50 [lx], and 200 [cd / m ² ] when the illuminance is 2500 to 5000 [lx]. A value of 200 [cd / m ² ] is set in ascending order. The LCD unit luminance can be appropriately updated according to the installation environment and specifications of the portable terminal 10.

  In the set value reference table 131, a value is set as the LCD unit set value so that each of the LCD units 151a and 152a takes the corresponding brightness in accordance with the detection of the corresponding illuminance. The LCD unit setting value is a current value that the LCD flows through the backlight. That is, the set values of the LCD units 151a and 152a are values of currents flowing through the backlights 151 and 152 that illuminate the corresponding screen, and the luminance of the LCD units 151a and 152a is determined according to this value. As the set value is larger, the amount of current flowing through the backlight is increased, so that the luminance value is increased and the screen is brightened. On the contrary, when the set value is small, the current flowing through the backlight is decreased, so that the luminance value is also small and the screen is darkened.

In this embodiment, the set value is set in hexadecimal, but may be other numbers such as binary and decimal. For example, regarding the backlight 151 and the LCD unit 151a, when the setting value is 03 [Hex] and the LCD unit luminance is a specification that takes a value of 35 [cd / m ² ], the illuminance is 0 to 50 [lx]. A value of 03 [Hex] is set in the corresponding storage area (memory address). Further, for example, regarding the backlight 152 and the LCD unit 152a, when the setting value is 2A [Hex] and the LCD unit luminance is a specification of 150 [cd / m ² ], the illuminance is 200 to 700 [lx]. ] Is set to a storage area (memory address) corresponding to 2A [Hex]. Note that these LCD unit set values can also be changed as appropriate according to the specifications of the backlight and the LCD unit and the installation ring.

  The backlight control ICs 141 and 142 adjust the brightness of the LCD units 151a and 152a by controlling the current from the power supply unit to the backlights 151 and 152 in accordance with the brightness setting value notified from the processor 12.

  The backlights 151 and 152 respectively illuminate the LCD units 151a and 152a from the back using three-color LEDs (Light Emitting Diodes) as light sources. In other words, the backlights 151 and 152 illuminate the LCD units 151a and 152a from the back so that the LCD units 151a and 152a have a set brightness corresponding to the illuminance, under the control of the backlight control ICs 141 and 142.

  Next, the operation of the portable terminal 10 in this embodiment will be described.

  FIG. 4 is a diagram for explaining the operation of the portable terminal 10. In S1, when the illuminance sensor 11 detects the illuminance around the portable terminal 10, the illuminance detection result is notified to the processor 12 via the OS or the driver (S2).

  The processor 12 monitors the input of the illuminance detection result from the illuminance sensor 11, and when receiving the input from the illuminance sensor 11, the processor 12 requests the memory 13 to read the set value (S3). The read request includes the ambient illuminance value as the illuminance detection result notified in S2. In response to the instruction from the processor 12, the memory 13 reads the set values of the LCD units 151a and 152a corresponding to the illuminance value and responds to the processor 12 (S4). For example, when the illuminance value included in the set value read request is 150 [lx], the processor 12 tries to read the set value corresponding to the illuminance value 150 [lx]. In the memory 13, 10 [Hex] and 1B [Hex] are stored in a setting value storage area corresponding to the illuminance value 150 [lx] (see FIG. 3). Therefore, the processor 12 acquires 10 [Hex] as the setting value of the LCD unit 151 a and 1 B [Hex] as the setting value of the LCD unit 152 a from the memory 13.

  Subsequently, the processor 12 notifies the corresponding LED driver of the setting values of the LCD units 151a and 152a acquired in S4 (S5). In the above example, the setting value 10 [Hex] is notified to the LED driver corresponding to the LCD unit 151a, and the setting value 1B [Hex] is notified to the LED driver corresponding to the LCD unit 152a. . Each LED driver controls the backlights 151 and 152 according to the LCD units 151a and 152a based on the setting value notified in S5, thereby adjusting the brightness of both screens to be the same ( S6).

In the above example, since the LED driver corresponding to the LCD unit 151a is notified of 10 [Hex] as the setting value, the LED driver supplies a current having a strength corresponding to the setting value 10 [Hex] to the backlight 151. To control the luminance of the LCD unit 151a to 100 [cd / m ² ]. Similarly, since the LED driver corresponding to the LCD unit 152a is notified of 1B [Hex] as the setting value, the LED driver supplies a current having a strength corresponding to the setting value 1B [Hex] to the backlight 152. Thus, the brightness of the LCD unit 152a is controlled to 100 [cd / m ² ]. Thereby, the luminance of the LCD units 151a and 152a is unified to 100 [cd / m ² ].

  Next, processing executed by the processor 12 of the portable terminal 10 will be described.

  FIG. 5 is a diagram for explaining processing executed by the processor 12. In S <b> 11, the processor 12 monitors whether or not the illuminance sensor 11 detects illuminance, and acquires the illuminance from the illuminance sensor 11. In S12, the processor 12 refers to the setting value reference table 131 in the memory 13, and acquires the luminance setting value of the LCD unit 151a corresponding to the illuminance acquired in S11. In S13, the processor 12 executes the same processing as in S12 regarding the LCD unit 152a. That is, the processor 12 refers to the setting value reference table 131 in the memory 13 and acquires the luminance setting value of the LCD unit 152a corresponding to the illuminance acquired in S11.

  In S14, the processor 12 notifies the LCD unit 151a of the luminance setting value acquired from the setting value reference table 131 in S12. In S15, the processor 12 performs the same processing as in S14 on the LCD unit 152a. That is, the processor 12 notifies the LCD unit 152a of the luminance setting value acquired from the setting value reference table 131 in S13. After that, the processor 12 waits for the elapse of a predetermined time (S16), and when the predetermined time elapses (S16; Yes), the processor 12 monitors whether or not a power-off instruction is input by the user (S17). While there is no power-off instruction input (S17; No), the processor 12 repeatedly executes the above-described series of processes of S11 to S16. On the other hand, in response to the instruction to turn off the power (S17; Yes), the processor 12 ends the above series of processing.

  As described above, the portable terminal 10 includes the illuminance sensor 11, the processor 12, and the plurality of LCD units 151a and 152a. The processor 12 acquires illuminance from the illuminance sensor 11. The processor 12 sets the LCD units 151a, 152a corresponding to the acquired illuminance from the setting value reference table 131 in which the illuminance, the luminance setting value of the LCD unit 151a, and the luminance setting value of the LCD unit 152a are stored in association with each other. Each brightness setting value is acquired. The processor 12 notifies the LCD unit 151a of the acquired brightness setting value of the LCD unit 151a, and notifies the LCD unit 152a of the acquired brightness setting value of the LCD unit 152a. The LCD unit 151a and the LCD unit 152a that have received the notification of the luminance setting value from the processor 12 adjust the LCD screen luminance based on the luminance setting value. Accordingly, the screen brightness of the LCD units 151a and 152a is unified so as to be the same.

  That is, the portable terminal 10 according to the present embodiment includes a plurality of LCD units 151a and 152a. The portable terminal 10 includes an illuminance sensor 11, a memory 13, a processor 12, and an LED driver. The illuminance sensor 11 detects illuminance. The memory 13 stores illuminance and setting values for determining the brightness of the LCD units 151a and 152a in association with each LCD unit. The processor 12 inputs the illuminance detected by the illuminance sensor 11, acquires a setting value corresponding to the illuminance from the memory 13, and outputs it. The LED driver controls the luminance of the plurality of LCD units 151a and 152a based on the setting value output by the processor 12. That is, the portable terminal 10 detects the ambient illuminance by the single illuminance sensor 11, and controls the backlights 151 and 152 based on the illuminance so that the luminance of the plurality of LCD units 151a and 152a is the same. Thus, the luminance difference is reduced, and the visibility of the screen is improved.

  In other words, the portable terminal 10 once notifies information detected by the single illuminance sensor 11 to an application (driver, OS, etc.) on the host (CPU) side, and based on the information, the two LCD units Write control of luminance information 151a and 152a is performed. FIG. 6A is a diagram illustrating an example of a display screen before such luminance control is performed. Before the brightness control, the brightness of the LCD units 153a and 154a is different, and the brightness of the LCD unit 154a is lower than the brightness of the LCD unit 153a for some reason. As a result, the lower half is displayed darker than the upper half of the letters “example”. When the portable terminal 10 performs the above-described writing control, the luminance difference between the two LCD units is reduced, and the luminances of the LCD units 151a and 152a have the same value. Thereby, the upper half and the lower half of the characters “example” are displayed with the same brightness, and the display state (the state shown in FIG. 6B) is easy for the user to see.

  In addition, since the portable terminal 10 controls the luminance of the two LCD units 151a and 152a by using one illuminance sensor 11, the following effects are secondary. That is, as compared with the conventional case having two or more illuminance sensors, the circuit constituting the illuminance sensor can be downsized and the wiring can be simplified. Thereby, the mounting area for realizing the luminance control is reduced, and the device itself can be downsized. Moreover, in order to mount an illuminance sensor on the portable terminal 10, it is necessary to provide a light receiving opening on the front surface of the terminal casing. However, if there is one illuminance sensor, it is necessary to provide a plurality of openings. Therefore, the case processing can be simplified correspondingly.

  Further, if the single illuminance sensor 11 is used as in the portable terminal 10 according to the present embodiment, there is no concern that the timing of illuminance detection is shifted between the sensors. This avoids the inconvenience that the brightness is adjusted only for one screen and the brightness is not adjusted on the other screen. Accordingly, characters and images having the same luminance suitable for the ambient illuminance are always displayed on the LCD units 151a and 152a of the portable terminal 10. As a result, an easy-to-view screen display is realized.

  Furthermore, the setting value reference table 131 included in the portable terminal 10 according to the present embodiment is configured to be updatable. That is, the LCD unit setting values stored in the setting value reference table 131 can be adjusted automatically or manually so that the screen display can be performed with a luminance suitable for the ambient illuminance. As a result, the LCD unit of the portable terminal 10 is appropriately adjusted to the same luminance according to the ambient illuminance through the setting value unique to each LCD unit, regardless of the type and specification of the LCD. Therefore, the portable terminal 10 can unify the luminance of the two LCD units not only for LCDs having different configurations and specifications but also for individual differences between LCDs having the same configuration and specifications. In addition, even when one or both of the LCD units are exchanged or an LCD unit is added for some reason, it is possible to easily cope with it. That is, the portable terminal 10 can make the screen brightness of the LCD the same as the brightness of the previous LCD unit by a simple operation of adjusting the setting value of the table in accordance with the new LCD. Therefore, even when the LCD is replaced or added, a difference in luminance does not occur on different screens and it is not easy to see. As a result, the convenience and versatility of the portable terminal 10 are improved.

[Brightness control program]
The various processes described in the above embodiments can be realized by executing a prepared program on a computer. Therefore, in the following, an example of a computer that executes a brightness control program having the same function as that of the portable terminal 10 illustrated in FIG. 2 will be described with reference to FIG.

  FIG. 7 is a diagram illustrating a computer that executes a brightness control program. As shown in FIG. 7, the computer 100 includes a CPU 110, an input device 120, a monitor 130, a voice input / output device 140, a wireless communication device 150, and an illuminance sensor 160. Further, the computer 100 includes a RAM 170 and a data storage device such as a hard disk device 180, which are connected by a bus 190. The CPU 110 executes various arithmetic processes. The input device 120 receives data input from the user. The monitor 130 displays various information. The voice input / output device 140 inputs and outputs voice. The wireless communication device 150 exchanges data with other computers via wireless communication. The illuminance sensor 160 detects ambient illuminance and outputs the detection result to the CPU 110 via the bus 190. The RAM 170 temporarily stores various information.

  The hard disk device 180 stores a brightness control program 181 having the same function as the processor 12 shown in FIG. Also, the hard disk device 180 includes brightness control processing related data 182 corresponding to various data (such as ambient illuminance, LCD unit brightness, LCD unit setting value) stored in the memory 13 shown in FIG. File 183 is stored.

  Then, the CPU 110 reads the luminance control program 181 from the hard disk device 180 and develops it in the RAM 170, so that the luminance control program 181 functions as the luminance control process 171. Then, the luminance control process 171 expands information read from the luminance control processing related data 182 to an area allocated to itself on the RAM 170 as appropriate, and executes various data processing based on the expanded data. Then, the luminance control process 171 outputs predetermined information to the luminance control history file 183.

  The brightness control program 181 is not necessarily stored in the hard disk device 180, and the computer 100 may read and execute this program stored in a storage medium such as a CD-ROM. . Further, this program may be stored in another computer (or server) connected to the computer 100 via a public line, the Internet, a LAN (Local Area Network), a WAN (Wide Area Network), or the like. In this case, the computer 100 reads the program from these and executes it.

  In the above embodiment, the portable terminal 10 has been described assuming various portable terminal devices such as a mobile phone, a smartphone, and a PDA (Personal Digital Assistant). However, the technology disclosed in the present application can be applied to various electronic devices having a plurality of display screens such as a car navigation system, a PC (Personal Computer), and a television. In the case of a portable terminal, if there are two illuminance sensors, one of them may be hidden by a finger depending on how it is held, or the detected illuminance may differ depending on the angle of the terminal. In this way, in the case of a portable terminal, a difference in brightness is likely to occur between the two LCD units. Therefore, it is particularly effective to make the brightness of both screens uniform by applying the above embodiment. However, even in a terminal device other than a portable terminal, the detected illuminance may be different depending on the installation method and the surrounding environment (the movement of a person or the position of an object). Therefore, the application of the above embodiment is effective not only for portable terminals but also for terminal devices other than portable terminals.

  In the above embodiment, the case where the portable terminal 10 includes two LCD units 151a and 152a has been described as an example. However, the number of LCD units may be three or more. Even in such an aspect, the portable terminal 10 additionally sets the setting values of three or more LCD units in the setting value reference table 131 for each illuminance and luminance, so that a plurality of screens can be displayed. The brightness shift at is adjusted. Therefore, the user of the portable terminal 10 can see three or more LCD units in an easy-to-see state (a state suitable for ambient illuminance and equal brightness of each screen).

  Further, each component of the illustrated portable terminal does not necessarily have to be physically configured as illustrated. That is, the specific mode of distribution / integration of each device is not limited to that shown in the figure, and all or a part thereof may be functionally or physically distributed or arbitrarily distributed in arbitrary units according to various loads or usage conditions. It can also be integrated and configured. For example, the processor 12 as the input / output unit and the backlight control ICs 141 and 142 as the control unit may be integrated as one component. On the contrary, regarding the processor 12, the detected illuminance may be input to a portion that is input, and the setting value corresponding to the illuminance may be acquired from the memory 13 and output. Further, the memory 13 may be connected as an external device of the portable terminal 10 via a network or a cable.

DESCRIPTION OF SYMBOLS 10 Portable terminal 10a Hinge 11 Illuminance sensor 12 Processor 13 Memory 131 Setting value reference table 141, 142 Backlight control IC
151, 152 Backlights 151a, 152a LCD unit 100 Computer 110 CPU
120 Input Device 130 Monitor 140 Audio Input / Output Device 150 Wireless Communication Device 160 Illuminance Sensor 170 RAM
171 Luminance control process 180 Hard disk device 181 Luminance control program 182 Luminance control processing related data 183 Luminance control history file 190 Bus

Claims (2)

An electronic device having an illuminance sensor, a processor, and a plurality of display units,
The processor is
Obtaining illuminance from the illuminance sensor;
The luminance setting of the first display unit corresponding to the illuminance acquired from the table in which the illuminance, the luminance setting value of the first display unit, and the luminance setting value of the second display unit are stored in association with each other. Value and the brightness setting value of the second display unit,
The acquired brightness setting value of the first display unit is notified to the first display unit, and the acquired brightness setting value of the second display unit is notified to the second display unit. Electronic equipment. A luminance control program executed by an electronic device having an illuminance sensor, a processor, and a plurality of display units,
Obtaining illuminance from the illuminance sensor;
The luminance setting of the first display unit corresponding to the illuminance acquired from the table in which the illuminance, the luminance setting value of the first display unit, and the luminance setting value of the second display unit are stored in association with each other. Value and the brightness setting value of the second display unit,
Notifying the first display unit of the acquired luminance setting value of the first display unit, and notifying the second display unit of the acquired luminance setting value of the second display unit. A brightness control program that is executed by the program.

Images