JP3967251B2 - Electronic device having 2D (2D) and 3D (3D) display functions - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electronic apparatus having a 2D (2D) and 3D (3D) display function.
[0002]
[Prior art]
In recent years, mobile devices such as mobile terminals, mobile personal computers and mobile phones, information devices such as desktop personal computers, and various electronic devices including audio / video devices have been improved in functionality.
[0003]
2. Description of the Related Art A conventional mobile phone with a 3D display function having a 3D display function has been proposed that can switch between 2D (2D) / 3D display. The lenticular lens disposed above the liquid crystal display is movable so that the display areas of the 2D display unit and the 3D display unit can be changed. (For example, refer to Patent Document 1.)
Usually, a screen called a standby screen is set as a default screen when the mobile phone is not used as a telephone. The standby screen can be arbitrarily set by the user by selecting a pre-registered image, an image taken with a camera, or an image downloaded with a browser such as a website or email.
In addition, the standby screen can be switched from the standby screen to a necessary operation screen or a necessary setting screen by performing a key operation or the like.
[0004]
In the mobile phone with 3D display provided with the 3D display function, it is proposed to adopt a 3D display screen as the standby screen.
[0005]
A configuration example of a 3D display that can be switched to 2D display will be described with reference to FIGS.
[0006]
FIG. 6 shows the pixel (pixel) layout of a standard type liquid crystal device (LCD). LCDs are used for color displays and are composed of red, green, and blue pixels denoted by R, G, and B. The pixels are arranged as columns Col0 to Col5 in which red, green and blue pixels are arranged vertically. Thus, the leftmost column Col0 of pixels displays the leftmost strip of the displayed image, the column Col1 adjacent to the right displays the next column of the image, and so on.
[0007]
The display of FIG. 7 is used to perform 3D stereoscopic display. The 3D display includes a liquid crystal display device (including a polarizing plate) 101 that functions as a spatial light modulator for adjusting the light from the backlight 102 according to the image content to be displayed. The parallax optical system operates in cooperation with the liquid crystal display device 101 to form a viewing window. FIG. 7 shows a front parallax barrier type 3D autostereoscopic display including a parallax barrier 103 as a parallax optical system. The parallax barrier 103 includes a plurality of slits that extend vertically and are arranged in parallel at equal intervals in the lateral direction, as indicated by reference numeral 104, and each slit is a pair of centers of pixel rows of individual colors. Located in. For example, the slit shown at 104 in FIG. 7 is aligned with the blue pixel column 105 and the green pixel column 106.
[0008]
In order to ensure that the left and right viewing windows are in the correct placement, the left and right image data is supplied to a liquid crystal display device 101 of the type shown in FIG. 7 in the manner shown in FIG. . In FIG. 8, the color image data of the leftmost strip of the left image is displayed by the red, green, and blue pixel columns shown on the left of Col0. Similarly, the color data of the leftmost strip of the right eye view is displayed by the column of pixels shown at Col0 right. This arrangement ensures that left and right view image data is sent to the appropriate left and right viewing windows. This arrangement also ensures that all three pixel colors R, G, and B are used to display each view strip.
[0009]
Thus, compared to the layout shown in FIG. 6, in the layout shown in FIG. 8, the red and blue pixels in the leftmost column display the image data of the left view, while the green in the leftmost column. The pixel displays the image data of the right view. In the next column, red and blue pixels display the image data of the right view, while green pixels display the image data of the left view. Thus, when using a standard liquid crystal display device of the type shown in FIGS. 6-8, image data for the left and right views while “swapping” the green component between columns of RGB pixels. Must be interlaced. Of course, depending on the display settings, in addition to the green component, the red or blue component may be replaced.
[0010]
FIG. 9 shows a part of the display controller. The data to be displayed is supplied in serial form on the data bus 120 and the address defining the pixel arrangement on the screen is supplied on the address bus 121. The data bus 120 is connected to the inputs of several banks of random access memory (two shown in the drawing) such as memories (VRAM) 122 and 123. The address bus 121 is connected to the memory management system 124. The memory management system 124 converts the screen address into a memory address that is supplied to the address inputs of the memories 122 and 123.
[0011]
The output ports of the memories 122 and 123 are connected to the first-in first-out (FIFO) register 125 of the video controller 126 via the latch circuit 130. The memories 122 and 123 and the register 125 are controlled so that individual pixel data are alternately read from the memories 122 and 123 and supplied to the display memory (VRAM) 127 in the correct order. The display memory 127 is a display memory that temporarily stores display data rearranged between the driver circuit of the liquid crystal display device 101.
[0012]
FIG. 10 shows the latch circuit 130 in more detail. The latch circuit 130 includes latches 140 and 141 connected to the output ports of the memories 122 and 123, respectively. Each of the latches 140 and 141 comprises 24 1-bit latches arranged as a group of 8 latching R, G, B data from the respective memory. Latches 140 and 141 connect together latch enable inputs and connect them to the output of timing generator 128 that provides latch enable signal L.
[0013]
The latch circuit 130 further includes three switching circuits 142, 143, and 144, each of which includes eight individual switching elements having control inputs connected together. The control inputs of the switching circuits 142, 143, and 144 are connected together and connected to the output of the timing generator 128 that supplies the switching signal SW. Timing generator 128 has a further output that provides write enable signal F to register 125.
[0014]
Here, it should be noted that the switching circuit 143 corresponding to the G data is different from the other switching circuits 142 and 144 in the switching destination for the latch circuits 140 and 141.
[0015]
When the display data is available at the output ports of the memories 122 and 123, the latch enable signal L is high. In this way, the latches 140 and 141 latch display data. Immediately after the latch enable signal L returns to low, the switching signal SW rises to a high level. Next, the switching circuits 142, 143, and 144 are switched to the state shown in FIG. 10, and the R, G, and B outputs of the latch 140 are connected to the register 125. Next, the write enable signal F is supplied to the register 125, and the RGB data from the latch 140 is written to the register 125. Further next, the write enable signal F is disabled to prevent further data from being written to the register 125 until the next write enable signal.
[0016]
Next, the switching signal SW becomes low level, and the switching circuits 142, 143, and 144 connect the output of the latch 141 to the register 125. A further write enable signal F is generated, and the data from the latch 141 is written to the register 125. At this time, the data written in the register 125 at the same time is written in the display memory 127. The next latch enable signal L becomes high, and the same processing is repeated. In this way, data is written from the memories 122 and 123 to the register 125 alternately. The data written in the register 125 is sequentially written in the display memory 127, and the process is repeated until the data necessary for displaying one screen is written in the display memory 127.
[0017]
When writing 2D or monoscope data that must be displayed for both eyes of the observer: In this case, the parallax optical system by the parallax barrier 3 is removed. The monoscope pixel data is directly input and stored in the display memory 127 shown in FIG. In the 3D display mode, each of the left and right eye images has a resolution that is half the horizontal spatial resolution of the liquid crystal display device 101. When operating in the 2D or monoscope mode, the resolution is twice the horizontal resolution of the liquid crystal display device 101 as compared with the 2D image.
[0018]
The parallax optical system may be selectable for its formation. FIG. 11 shows a display device configured to selectively switch between 2D and 3D images by selectively forming a parallax optical system. Here, the parallax optical system uses, for example, a liquid crystal device (LCD) 150 for switching 2D / 3D and a patterned retardation plate 151 as shown in the drawing for the above. Here, the switching liquid crystal device 150 is a solid electrode in order to switch the entire surface between 3D and 2D. The patterned retardation plate 151 is replaced with one of the two polarizing plates of the liquid crystal device. 11, parts having substantially the same functions as those in FIG. 7 are denoted by the same reference numerals. In the example of FIG. 11, the parallax barrier 103 ′ is disposed on the back surface of the liquid crystal display device 101, that is, on the backlight 102 side, but may be disposed on the front surface side of the liquid crystal display device 101 as illustrated in FIG. 7.
[0019]
In the arrangement as shown in FIG. 11, when displaying a 3D image, no voltage is applied to the switching liquid crystal device 150. As a result, the liquid crystal molecules in the inside maintain a rotated state, and a slit substantially similar to the slit 104 of the parallax barrier 103 of FIG. 7 according to the pattern of the patterned retardation plate 151 due to the polarization characteristics of light with respect to the patterned retardation plate 151. Form. When displaying a 2D image, the rotation of the liquid crystal molecules is released by applying a voltage to the switching liquid crystal device 150, and the patterned retardation plate 151 influences the input light on the pattern retardation plate regardless of the presence or absence of the pattern. This can be achieved by eliminating the formation of slits.
[0020]
Note that the 2D image is displayed on the 3D autostereoscopic display having a fixedly formed parallax optical system as shown in FIG. It is possible to display with a 2D image. However, in this case, the parallax optical system is still formed on the display itself, and even when a 2D image is displayed, the parallax optical system is affected when the user views the display.
[0021]
On the other hand, when the formation of the parallax optical system is selectively performed as shown in FIG. 11, there is an advantage that the display of the 2D image can be performed without the influence of the parallax. That is, in the case of the arrangement as shown in FIG. 11, when a 2D image display is selected, a normally used liquid crystal display device in which no parallax optical system is formed in part or all of the displayed area. The device structure is substantially the same as the above, and can be easily visually recognized from any position without being affected by the left and right parallax.
[0022]
[Patent Document 1]
JP 2001-251403 A (pages 4-12, FIG. 9)
[0023]
[Problems to be solved by the invention]
As described above, in a device that switches between 2D and 3D images for display, for example, the operation of the switching liquid crystal device 150 that is one component of the parallax optical system is switched and input to the display memory 127. It is necessary to change the structure of data.
[0024]
The 3D image screen is a device for switching and displaying 2D and 3D images. In the 3D image display mode, the display data of the left eye and the right eye is input to the video controller 126 and rearranged by the video controller 126. Can be displayed in 3D form.
[0025]
The same applies to the case where the user arbitrarily selects and plays back a pre-registered image, an image taken with a camera, or an image downloaded with a browser such as a website or e-mail, with the display set to a 3D image display mode. It is.
[0026]
However, since such a 3D display needs to be viewed from a specific direction, it may be difficult to keep viewing the display for a long time.
[0027]
The present invention forcibly changes the display of a 3D image to display of a 2D image by a key operation, a preset timer time, or the like in an electronic device having display means for selectively switching and displaying 2D and 3D images. It can be switched.
[0028]
[Means for Solving the Problems]
1st invention is an electronic device provided with the display means by which 2D and 3D image are selectively switched and displayed, Comprising: The image data for displaying the 2D image and the 3D image in the display means is stored Storage means, communication means for communicating signals, forced display switching means for forcibly switching to 2D image display at the time of 3D image display based on reception of the signal by the communication means, and backlight control means The backlight control means always turns on the backlight during 3D image display, and turns off the backlight after the 3D image display is switched to 2D image display by the forced display switching means. Dimensional) and 3D (three-dimensional) display device.
[0029]
According to a second aspect of the present invention, there is provided an electronic apparatus including display means for selectively switching and displaying 2D and 3D images, and storing the image data for displaying the 2D image and the 3D image in the display means. Storage means, communication means for communicating signals, key input means, forced display switching means for forcibly switching to 2D image display based on a key input operation by the key input means when displaying a 3D image , back A light control means , and the backlight control means always turns on the backlight during the 3D image display, and turns off the backlight after the 3D image display is switched to the 2D image display by the forced display switching means. It is an electronic device having a characteristic 2D (2D) and 3D (3D) display function.
[0030]
According to a third aspect of the present invention, there is provided storage means for storing the 2D image and the image data for displaying the 3D image in the display means, communication means for communicating a signal, and display time of the 3D image on the display means. and time counting means for counting, the forced display switching means forcibly switches the 2D image of the 3D image display with a lapse of a predetermined time in said time counting means, provided a backlight control unit, the backlight control means, 2D (2D) and 3D (3D) characterized in that the backlight is always turned on during 3D image display and the backlight is turned off after the 3D image display is switched to 2D image display by the forced display switching means. An electronic device having a display function.
[0033]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view showing an external appearance of a clamshell type camera-equipped mobile phone 1 according to an embodiment of the present invention.
[0034]
The mobile phone 1 includes a first housing 2 and a second housing 3, and the first housing 2 and the second housing 3 are connected via a hinge 4 and angularly displaced with the hinge 4 as an axis. It can be folded by moving freely. As shown in FIG. 1, the mobile phone 1 includes a first display unit 5 in a first housing 2. The first display unit 5 is arranged so as to be located inside when the mobile phone 1 is folded. The 1st display part 5 is a display body which electrically switches and displays 2D and 3D images, and displays the image based on the image data sent via the 1st display driver part 43 mentioned later. The first display unit 5 is provided with a first speaker 6 used during a call.
[0035]
Next, the 2nd housing | casing 3 of the mobile telephone 1 which is one Embodiment of this invention is demonstrated. The input button group 7 includes keys and the like for inputting numbers and characters. The function button group 8 is a button group for performing various settings / function switching in the cellular phone, and includes a power button 9 for switching on / off the power, a first shutter button 10 for a camera function to be described later, a mail function and guidance. A mail / guidance button 11 for displaying, a start / speaker receiving button 12 for starting a call and receiving a speaker, a multi-guide button 13 comprising a four-way button and a determination button for selecting and determining up / down / left / right on the function selection screen. Consists of In addition, a transmission microphone 14 is provided at the bottom of the second housing 3.
[0036]
The arrangement of the second casing 3 of the cellular phone 1 is normally arranged in the order of the hinge 4, the function button group 8, the input button group 7, and the transmission microphone 14, but is not limited thereto. It is not a thing.
[0037]
FIG. 2 is an external perspective view of the cellular phone 1 in a folded state. As shown in FIG. 2, the camera unit 21 and the light unit 22 are arranged in order from the hinge 4 side on the back surface of the first housing 2, and the second display unit 20, the second shutter button 23, and the first shutter unit 23 are arranged. Two operation button groups 24 are arranged subsequently.
[0038]
The second display unit 20 is arranged so as to be located outside when the mobile phone 1 is folded. The second display unit 20 is realized by a liquid crystal display, an EL display, or the like. An image based on image data of a character image such as a captured image, time information, radio wave intensity, and mail reception display sent via a second display driver unit 44 described later is displayed. When displaying these images, the image data sent from the second display driver unit 44 to the second display unit 20 is displayed so that the direction of the hinge 4 is upward when displayed. The second display unit 20 displays an image so that the direction of the hinge 4 is upward, so that when the user uses the cellular phone 1 in a folded state, the user uses the hinge upward. Whether the user opens or closes the mobile phone 1, the orientation of the second housing 3 does not change. In other words, each time the mobile phone 1 is opened or closed, it is not necessary to change the direction of the mobile phone 1 or to change it, so that operability and convenience are improved. The image display on the second display unit 20 includes a captured image, and even when the captured image is viewed, it is not necessary to change the direction of the mobile phone 1 or to change it, thereby improving operability and convenience.
[0039]
The camera unit 21 includes an imaging lens, an imaging device such as a CCD (Charge Coupled Device) image sensor or a CMOS (Complementary Metal Oxide Semiconductor) image sensor, and RGB color filters. The camera unit 21 converts the light reflected by the subject and incident on the imaging lens into RGB three-color light through a color filter, and converts the RGB three-color light into the image sensor. As shown in FIG. 2, the camera unit 21 is provided outside when the cellular phone 1 is folded, and is positioned between the hinge 4 and the second display unit. When the user opens the mobile phone 1 and takes a picture, the user holds the second casing 3 and takes the picture.
[0040]
The light unit 22 is used as an auxiliary light source when the camera unit 21 captures an image. In general, there are many that use a xenon tube, but recently, there is also an auxiliary light source that emits white light by simultaneously emitting RGB LEDs.
[0041]
The second shutter button 23 is arranged at the center of the back surface of the first housing 2 and is located below the second display unit 20 when the cellular phone 1 shown in FIG. 2 is folded. By disposing the second shutter button 23 at this position, the user can easily confirm the shutter button position in a folded state and easily take a picture.
[0042]
In addition, second operation button groups 24 a and 24 b for performing various settings / operations using the second display unit 20 are provided on both sides of the second shutter button 23. The second operation button group can operate various function settings, address book display / search, mail confirmation / display / send in conjunction with the second display unit 20. In addition, it is possible to operate zoom operations during shooting and forward / backward feeding of a plurality of captured images.
[0043]
The rear surface of the second casing 3 includes an antenna unit 25 and a helical unit 26 that can be moved up and down, a battery unit that stores a battery, and a second speaker that rings a ring tone (not shown).
[0044]
The first casing 2 is mechanically connected to the second casing 3 through the hinge 4, and the first casing 2 and the second casing 3 are electrically connected in the hinge 4. A flexible substrate is incorporated.
[0045]
FIG. 3 shows an example of the internal circuit configuration of the mobile phone 1.
[0046]
The control unit 40 is a control unit that controls the operation of each part constituting the mobile phone 1, a shutter button control unit, a backlight control unit, a light control unit, and a display control unit. The image processing unit 41 includes an amplification unit, an A / D (analog / digital) conversion unit, and a signal processing unit. The amplifying unit amplifies the electrical signal corresponding to RGB sent from the camera unit 21 and sends it to the A / D conversion unit. The A / D conversion unit converts the electrical signal (analog) corresponding to RGB converted by the amplification unit into a digital signal, outputs image data, and sends the image data to the signal processing unit. The signal processing unit performs signal processing such as pixel interpolation processing on the image data sent from the A / D conversion unit. The signal processing unit sends the image data subjected to the signal processing to the first memory 42 based on the control signal sent from the control unit 40. The camera unit 21 and the image processing unit 41 are imaging means that converts incident light into an electrical signal and outputs it as image data. The first memory 42 temporarily stores image data continuously sent from the signal processing unit. For example, temporally old image data is temporarily stored by deleting or overwriting the newest image data.
[0047]
The control unit 40 transmits a control signal to the first and second display driver units 43 and 44 and sends the image data stored in the first memory 42 to the first and second display driver units 43 and 44. The first and second driver units 43 and 44 drive voltage to the pixel electrodes of the first and second display units 5 and 20 in accordance with image data to be displayed on the first and second display units 5 and 20. Apply.
[0048]
The first and second backlights 45 and 46 are composed of light emitting diodes as light emitting elements, and increase the luminance by applying light to the first and second display units 5 and 20. Control such as turning on and off of the first and second backlights 45 and 46 and brightness adjustment are performed by the control unit 40. The first operation button group 47 includes the input button group 7 and the function button group 8 of the second casing 3 described above. The second operation button group is installed in the first housing 2 as described above.
[0049]
The first and second shutter buttons 10 and 23 are continuously sent to the first memory 42, and the image data that the user desires to save is stored in the third memory 52 from among the temporarily stored image data. When the data is stored, the control signal is output to the control unit 40 by the user. The control unit 40 saves the image data stored in the first memory 42 in the third memory 52 in response to the instruction signals from the first and second shutter buttons 10 and 23. The second memory 48 is a memory used when displaying image data like the first memory 42.
[0050]
The open / close detection unit 49 is detection means for detecting whether or not the mobile phone 1 is folded. A detection switch (not shown) is provided inside the hinge 4, and a signal is sent to the control unit 40 according to the open / closed state, and the control unit 40 determines whether the cellular phone 1 is folded.
[0051]
The antenna unit 25 transmits and receives voice data, character data, image data, and the like when performing wireless communication with a base station via wireless radio waves. The radio unit 50 demodulates data received from the base station via the antenna unit 25 at the time of reception, and character data and image data sent from the communication control unit 51 based on a predetermined protocol at the time of transmission. This is sent to the control unit 40. Received data from the other party received via the radio unit 50 and the communication control unit 51 is stored in the third memory 52.
[0052]
The control unit 40 switches the display unit that displays an image based on the image data temporarily stored in the first memory 42 based on the detection result of the open / close detection unit 49. When the open / close detection unit 49 detects that the cellular phone 1 is folded, the control unit 40 outputs the image data from the first memory 42 to the second display driver unit 44, and the second display unit 20. Display an image on. When the open / close detection unit 49 detects that the mobile phone 1 is not folded (opened), the control unit 40 outputs the image data from the first memory 42 to the first display driver unit 43, An image is displayed on the first display unit 5.
[0053]
Since the camera unit 21 is provided outside the cellular phone 1 when it is folded, when the subject other than the photographer of the cellular phone 1 is imaged, the photographer opens the cellular phone 1 with the camera open. An image is taken with the unit 21 facing the subject on the opposite side of the user. In this state, the open / close detection unit 49 detects that the mobile phone 1 is open, that is, is not folded, and an image based on the image data output from the camera unit 21 is displayed on the first display unit 5. . As a result, the user can use the first display unit 5 as a finder during imaging.
[0054]
On the other hand, when the photographer himself / herself is imaged as a subject, the photographer images the camera unit 21 toward the user with the cellular phone 1 folded. In this state, the open / close detection unit 49 detects that the cellular phone 1 is folded, and an image based on the image data output from the camera unit 21 is displayed on the second display unit 20.
[0055]
Thus, the photographer can use the second display unit 20 as a viewfinder at the time of photographing. Note that the mobile phone 1 according to the embodiment of the present invention can photograph the user himself / herself even when the mobile phone 1 is opened.
[0056]
The first display unit 5 includes a display device that can selectively display a 2D image and a 3D image by selectively forming a parallax optical system as described in FIG. The second display unit 20 includes a normal display device that displays only a 2D image. The first display driver unit 43 connected to the first display unit 5 includes the memories 122 and 123 and the video controller 126 described with reference to FIG.
[0057]
When taking an image taken from the camera unit 21 while using the first display unit 5 as a viewfinder, the first display unit 5 is set to a 2D image display mode. That is, when the mobile phone of this embodiment is set to the imaging mode by a key operation or the like, the first display unit 5 is set to the 2D image display mode. The image captured by the camera unit 21 is normally generated as a 2D image without being distinguished from the left-eye and right-eye images until it is converted specifically for a 3D image. Accordingly, in the first display unit 5, the 2D / 3D switching liquid crystal device 150 is switched to 2D image, and image data captured by the camera unit 21 is stored in the first display driver unit 43 from the first memory 42. The data is directly input to the display memory 127 of the video controller 126. Thus, an image captured by the camera unit 21 is displayed in real time until the shutter is operated as a finder in 2D display.
[0058]
In the first display unit 5, the display of the 3D image can be used, for example, when the 3D image data is sent as e-mail content as 3D image data and is received by the mobile phone of this embodiment. The content is preferably an animation, a landscape photograph, or other content that is more appropriate to be displayed as a 3D image than 2D, or content that is more enjoyable in 3D, but is not limited thereto. However, in the present embodiment, the received data needs to be image data divided into the left eye and the right eye as the data structure of the content due to the characteristics of the display device. Alternatively, by incorporating a 3D conversion function in the mobile phone, the image taken by the camera unit provided in the mobile phone itself may be converted into 3D image data divided into the left eye and the right eye for display. Alternatively, it may be used when 3D image data is transmitted from another mobile phone having the same function and received and displayed.
[0059]
The standby screen is normally set as a default screen when the cellular phone is not used as a telephone. The standby screen can be arbitrarily set by the user by selecting a pre-registered image, an image taken with a camera, or an image downloaded with a browser such as a website or email. The 3D display is suitable for displaying a photograph, a picture, or an animation by a bitmap, and can be a screen that can be enjoyed.
[0060]
FIG. 4 is a flowchart for explaining an operation example in which the 3D mode is switched to the 2D mode and the display is forcibly switched from the 3D image display to the 2D image display. In the mobile phone, the control unit 40 and an arbitrary memory unit constitute counting means for counting the display time of the 3D image, and the time counting means counts the display time of the 3D image.
[0061]
In the following example, the case where the 3D image standby screen is displayed on the first display unit 5 will be described. As described above, the content of the 3D image data received from the website or mail is played back. The same applies to the case where the image taken by the camera unit provided in the mobile phone is converted into 3D image data and displayed, or when the image taken in advance is reproduced from the memory in which the image is recorded.
[0062]
The 3D standby screen is normally set as a default screen, and as described above, the user selects a pre-registered image, an image taken with a camera, or an image downloaded with a browser such as a website or email. It can be set arbitrarily. When setting as a default screen, 3D data for a 3D standby screen is read from the third memory 52 to the first memory 42 (S21). The 3D data read to the first memory 42 is input to the first display driver unit 43, and a standby screen is displayed as a 3D image on the first display unit 5 (S22).
[0063]
When any of the keys (key group 7, 8, etc. in FIG. 1) is input when the standby screen set in this way is displayed (S23), the display mode of the first display unit 5 is changed from 3D to 2D display. When the mode is switched (S24), the display data of the 2D image is read from the third memory 52 to the first memory 42 (S25) and input to the first display driver unit 43 and displayed (S26). The 2D image data to be switched may be a warning display or a 2D image standby screen set in advance as a 2D image standby screen. In the example of FIG. 4, an example in which forced switching is changed to a 2D standby screen while the standby screen is maintained is shown.
[0064]
Here, any key operation is forcibly switched to display of a 2D image. Therefore, when it becomes difficult to see the display of the 3D image, it is possible to forcibly switch to the display of the 2D image by operating any key operation without any choice. Of course, there is no problem even if the display is switched to the 2D image display only by any selected key operation.
[0065]
If it is not key input, when the preset time is reached by the 3D image display time counting means (S34), the display mode can be switched to the 2D display mode in the same manner (S24). The standby screen 2D data is read from the third memory 52 to the first memory 42 (S25) and input to the first display driver unit 43, whereby the standby screen is displayed as a 2D image on the first display unit 5 (S26). ).
[0066]
As described above, the display in the 3D image can be forcibly switched to the 2D display by a predetermined time or a key operation. The set time may be set in advance by default, or the user may arbitrarily change the set time by a key operation or the like. In addition, the maximum allowable time information may be put in the content in advance, and this may be read as a predetermined time when the 3D image is displayed. As shown in the figure, even if it is not a preset time, for example, when the alarm setting time comes or when an incoming call or mail is received (S27), the 3D mode is switched to the 2D mode (S28). The alarm screen data may be read out or the incoming screen data may be read out (S29), and the respective data may be input to the first display driver unit 43 and displayed on the first display unit 5 (S30). In this case, it is convenient to display the 2D image so that the user can easily discriminate the alarm content or the incoming call content including characters without taking time.
[0067]
FIG. 5 shows the above display example, (a) is a 3D image standby screen display example, (b) is a 2D image standby screen display example after switching, and (c) is an incoming mail. It is an example of an incoming call screen display by a 2D image.
[0068]
Although not shown in the flowchart, after the display is switched to the 2D image display, the screen display on the first display unit 5 can be switched from the 2D image to the 3D image by any key operation. In this case, contrary to the above, the display mode of the first display unit 5 is switched to the 3D display mode, and 3D data for a 3D image screen is read from the third memory 52 to the first memory 42. A 3D image screen is displayed on the first display unit 5.
[0069]
As described above, the switching between the 3D image display and the 2D image display has been described. However, as described with reference to FIG. 7, the backlight is turned on to perform the 3D stereoscopic display. In order to use the device in a dark place, lighting the backlight is indispensable.
[0070]
However, since the backlight consumes a large amount of electricity, it is necessary for the portable device to control the backlight lighting time to increase the battery usage time.
[0071]
FIG. 12 is a schematic diagram showing the relationship between the 3D / 2D display time and the backlight lighting time. For example, the LCD display is a 3D display, and after a predetermined time display as described above, the display is forcibly switched to the 2D display. Shows the case.
[0072]
In FIG. 12, a line 200 indicates a time axis of 3D display and backlight lighting start. 201 indicates a 3D display state, and 203 indicates a 2D display state. A line 202 is a time axis for switching from 3D display to 2D display, and a line 204 is a time axis for turning off the display of the device.
[0073]
Reference numeral 205 denotes a backlight lighting state, and line 206 denotes a time axis at which the backlight is turned off. Reference numeral 207 denotes the time from the time axis 200 to the time axis 202, which is the same time as the 3D display state 201. That is, the backlight is always lit during the 3D display state. 208 indicates the time from when the 3D display is switched to the 2D display until the backlight is turned off, and 209 indicates the display time of the 2D display, which is the same time as the 2D display state 203.
[0074]
In FIG. 12, the 3D display time 207 may be preset by default, or the user may arbitrarily set the set time by a key operation or the like. In addition, the maximum display allowable time information may be put in the content in advance, and this may be read as a predetermined time when the 3D image is displayed.
[0075]
Similarly, the lighting time of the backlight may be set in advance as a default, or the user may arbitrarily set the lighting time by a key operation or the like. As described above, since the backlight is used during 3D display, the backlight is always turned on during 3D display. Then, after switching from the 3D display to the 2D display, measurement of the backlight setting time is started, and the backlight is turned off when the setting time is reached. Accordingly, in the case of FIG. 12, the time 208 is the backlight lighting setting time.
[0076]
Since the 2D display time is normally displayed unless the user intentionally turns off the power in a mobile phone or the like, or in the case of a foldable mobile phone or the like, it is normally displayed unless the user folds the mobile phone. It is better to set the backlight lighting time shorter than the time 209 in order to save electricity consumption. Note that the backlight may be turned off at the same time as the power of the device is turned off.
[0077]
In this way, the 3D display can be enjoyed by always turning on the backlight during 3D display. Then, after switching from 3D display to 2D display, measurement of the backlight lighting setting time is started, and if the backlight is turned off at the setting time, power consumption due to backlight lighting can be saved.
[0078]
Although not shown, if 3D display is performed again after 2D display, the backlight is naturally turned on, and the backlight is lit until at least 3D display is switched to 2D display.
[0079]
Note that the camera-equipped mobile phone 1 has been described as an embodiment of the present invention. However, even if there is no camera, the mobile phone 1 has a display unit that selectively displays 2D and 3D images. The present invention can be applied.
[0080]
In addition, for example, a user may display a 3D image currently captured by the camera on a display unit on a mobile phone equipped with a camera capable of capturing a 3D image, and actually shoot while viewing the 3D image.
[0081]
Furthermore, in the above example, the electronic device is described in which the first housing and the second housing are configured to be foldable by the connecting portion. However, even if there is one housing, 2D and 3D images are displayed. The present invention can be applied to any configuration provided with display means for selectively switching and displaying.
[0082]
In the above description, the first display unit 5 is configured as shown in FIG. 11 and can select the formation of a parallax optical system. However, a 2D image is displayed using a device as shown in FIG. In this case, the present invention can be applied even if the display data is changed so that the parallax observed by the left and right eyes is the same while the parallax optical system is formed.
[0083]
The present invention can be applied not only to mobile phones but also to various electronic devices including portable devices such as portable terminals and portable personal computers, information devices such as desktop personal computers, and audio / video devices.
[0084]
The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.
[0085]
【The invention's effect】
As described above, according to the present invention, in an electronic apparatus including a display unit that selectively displays 2D and 3D images, when a 3D image is displayed, a key input or a preset timer or an arbitrary The 2D image display is forcibly switched to the 2D image display for a set time by a timer that can be set to “2” and can be viewed on an easy-to-read 2D image screen.
[Brief description of the drawings]
FIG. 1 is an external perspective view of an electronic apparatus according to an embodiment.
FIG. 2 is an external perspective view of the electronic apparatus according to the present embodiment in a folded state.
FIG. 3 is a block diagram illustrating a configuration of an electronic device according to the present embodiment.
FIG. 4 is a flowchart showing a standby screen control process of the electronic device according to the present embodiment.
FIG. 5 is a diagram showing a display example of the electronic apparatus according to the embodiment.
FIG. 6 is a diagram showing a pixel layout of liquid crystal.
FIG. 7 is a cross-sectional view illustrating a configuration example of a 3D display device.
FIG. 8 is a pixel layout illustrating rearrangement for 3D display.
FIG. 9 is a block diagram illustrating a configuration example of a display controller.
FIG. 10 is a block diagram showing part of the details of the display controller.
FIG. 11 is a cross-sectional view illustrating a configuration example of a display device capable of 2D / 3D switching.
FIG. 12 is a schematic diagram showing a state of LCD display and backlight lighting.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Cellular phone 2 1st housing | casing 3 2nd housing | casing 5 1st display part 20 2nd display part 21 Camera part 40 Control part 42 1st memory 43 1st display driver part 52 3rd memory

Claims (3)

An electronic device including display means for selectively switching and displaying 2D and 3D images,
Storage means for storing image data for displaying the 2D image and the 3D image in the display means;
A communication means for communicating signals;
Forced display switching means for forcibly switching to 2D image display at the time of 3D image display based on reception of the signal by the communication means ;
A backlight control means ,
The backlight control means always turns on the backlight during at least 3D image display, and turns off the backlight after the 3D image display is switched to 2D image display by the forced display switching means. Dimension) and 3D (3D) display function electronic equipment. An electronic device including display means for selectively switching and displaying 2D and 3D images,
Storage means for storing image data for displaying the 2D image and the 3D image in the display means;
A communication means for communicating signals;
Key input means;
Forced display switching means for forcibly switching to 2D image display based on a key input operation by the key input means at the time of displaying a 3D image ;
A backlight control means ,
The backlight control means always turns on the backlight during at least 3D image display, and turns off the backlight after the 3D image display is switched to 2D image display by the forced display switching means. Dimension) and 3D (3D) display function electronic equipment. An electronic device including display means for selectively switching and displaying 2D and 3D images,
Storage means for storing image data for displaying the 2D image and the 3D image in the display means;
A communication means for communicating signals;
Time counting means for counting the display time of the 3D image on the display means;
Forced display switching means for forcibly switching 3D image display to 2D image display after a predetermined time in the time counting means ;
A backlight control means ,
The backlight control means always turns on the backlight during at least 3D image display, and turns off the backlight after the 3D image display is switched to 2D image display by the forced display switching means. Dimension) and 3D (3D) display function electronic equipment.

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