JP2007159015A - Portable device and digital camera - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a portable device which has good operability and give easy understanding of functions of operating buttons. <P>SOLUTION: Operating buttons 41-49 are provided on the back surface of a digital camera 10, and display panels 61-69 are each provided on the surface of each of the operating buttons 41-49. The brightness of the display panels 61-69 is switched with a brightness adjuster 136. When it is estimated that the vicinity of the digital camera 10 is bright based on a photometric value obtained by an AE detecting circuit 116, the brightness adjuster 136 in an automatic mode lights up the display panels 61-69 so that they can be easily viewed. When it is estimated that the vicinity is dark, the adjuster 136 suppresses the brightness of the display panels 61-69 to suppress power consumption. The brightness adjuster 136 in a manual mode switches the brightness of the display panels 61-69 in accordance with an operation of the user. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a portable device and a digital camera.

  In a mobile device such as a mobile phone or a digital camera, a plurality of functions are assigned to one operation button in order to suppress an increase in the number of operation buttons and realize downsizing. For example, in a digital camera, when an operation mode such as a shooting mode or a playback mode is switched, the function of the operation button is switched along with the switching. Further, an image representing the function of the operation button is printed on the surface of the operation button to prevent an erroneous operation.

However, there is a problem that the more functions a single button has, the more complicated the image printed on the operation buttons becomes. For this reason, Patent Document 1 below describes an apparatus that switches and displays images using a touch panel. According to this apparatus, since an image representing only the currently assigned function is displayed, it is simple and easy to see.
JP 10-27053 A

  However, the touch panel has a problem that it is difficult to obtain a feeling of operation and operability is poor. In addition, depending on the brightness around the mobile device, it is difficult to see the displayed image and it is difficult to understand the functions of the operation buttons.

  It is an object of the present invention to provide a portable device and a digital camera that have good operability and easy-to-understand operation button functions.

  In order to achieve the above object, a portable device according to the present invention includes an operation button whose function assigned according to the operation mode of the device changes, a display means arranged on the surface of the operation button, and brightness around the device. A brightness detection sensor for detecting brightness, and display control means for causing the display means to display an image corresponding to the function assigned to the operation button and switching the brightness of the image according to the brightness of the surroundings of the device It is characterized by having.

  An imaging unit that outputs the charge accumulated in each pixel according to the amount of light of the subject as an imaging signal may be provided, and the imaging unit may also be used as the brightness detection sensor.

  The image is preferably composed of a character or mark portion explaining the function and a background portion, and the display control means preferably switches the brightness of at least one of the character or mark portion and the background portion. .

  Furthermore, it is preferable that an operation member for manually switching the brightness of the image is provided.

  In order to achieve the above object, the digital camera of the present invention is characterized in that an image sensor that outputs an imaging signal obtained by photoelectrically converting a subject image is provided in the above-described portable device.

  According to the present invention, since the display means is provided on the surface of the operation button and an image corresponding to the function of the operation button is displayed, the operability is better than that of the touch panel. In addition, since the brightness of the image displayed on the display means is switched according to the brightness around the portable device, the image is easy to see and the function of the operation button is easy to understand.

  1 and 2, a digital camera 10 to which the present invention is applied includes a strobe light emitting unit 14 and a lens barrel 18 that holds an imaging lens 16 on the front surface of a camera body 12. On the upper surface of the camera body 12, a power button 20 for turning on / off the power, a mode selection button 22 for switching between modes such as a shooting mode, a playback mode, a menu mode, and the like for shooting. A release button 24 is provided. Further, a lid 28 is provided on the side surface of the camera body 12 to cover a memory card slot into which a memory card 26 (see FIG. 5) is detachably loaded.

  The release button 24 is a two-stage push switch, and when pressed lightly (half-press), various shooting preparation processes such as automatic exposure adjustment (AE) and automatic focus adjustment (AF) are performed. In this state, when the release button 24 is pressed again (fully pressed) once, the imaging signal for one screen subjected to the imaging preparation process is converted into image data, and then image processing and compression processing described later are performed. And stored in the memory card 26.

  On the back of the camera body 12, a liquid crystal display (LCD) 30 that functions as a monitor for performing various displays and an operation unit 32 that functions as input means for performing various operations are provided. On the LCD 30, a so-called through image is displayed in the photographing mode, an image recorded on the memory card 26 is reproduced and displayed in the reproduction mode, and a menu screen for performing various settings is displayed in the menu mode.

  The operation unit 32 is provided with a plurality of operation buttons 41 to 49. As shown in FIG. 3, the operation button 41 includes an operation member 50 and a press detection type switch 52 disposed behind the operation member. The operating member 50 is urged away from the switch 52 by a spring 54. When the operating member 50 is pressed toward the switch 52 against this urging, the switch 52 is activated and an operation signal is sent to the camera body 12. Entered.

  In addition, the operation button 41 is provided with a display panel 61 on the surface of the operation member 50. As shown in FIG. 4, the display panel 61 includes a dot matrix type organic EL display in which a plurality of pixels 61 a are arranged in a matrix, and is driven by a driver 71. Each pixel 61a includes a light emitting element that emits light according to the applied voltage value, and the driver 71 adjusts the driving voltage value for each pixel 61a to change the brightness for each pixel to form an image. To do. As a display panel driving method, there are a passive matrix method and an active matrix method in which a method of applying a driving voltage is different, and the display panel may be driven by any method.

  Similarly, the operation buttons 42 to 49 include operation members and switches. When the operation buttons 42 to 49 are pressed, an operation signal indicating this is input to the camera body 12. In addition, display panels 62 to 69 are disposed on the operation members of the operation buttons 42 to 49, respectively (see FIG. 2). The display panels 62 to 69 are driven by drivers 72 to 79 (see FIG. 7) to display various images.

  The functions assigned to the operation buttons 41 to 49 change according to the operation mode of the digital camera 10 (see FIG. 6). For example, in the shooting mode, the zoom magnification is changed by operating the operation buttons 41 and 42, and the operation button 44 is operated to shift to the screen adjustment mode described later, and the operation button 45 is operated. Then, the camera switches to the close-up shooting mode, and the operation button 47 is operated to switch the flash emission mode, and the operation button 48 is operated to shift to the self-timer use mode (see FIG. 9).

  In the playback mode, the playback image is enlarged and reduced by operating the operation buttons 41 and 42, and the print condition for designating the print condition of the recorded image data by operating the operation button 43. When the operation mode is changed to the designated mode and the operation button 44 is operated, the reproduced image is erased. When the operation buttons 45 and 47 are operated, the playback image is moved back and forward (see FIG. 10). In the playback mode, when the playback image is enlarged larger than the screen of the LCD 30, the display range of the playback image can be moved by the operation buttons 44, 45, 47, and 48, and the operation button 49 is operated. Thus, the enlargement / reduction of the image is canceled (see FIG. 11).

  Furthermore, in the menu mode, the operation buttons 44, 45, 47, and 48 are operated to move and display the cursor displayed in the menu screen, and the operation button 46 is operated to select the item selected by the cursor. The content is determined, and it is possible to return to the previous screen by operating the operation button 49 (see FIG. 12).

  Thus, by assigning a plurality of functions to one operation button, the number of operation buttons is reduced, and the digital camera 10 is downsized. Of course, the number and arrangement positions of the operation buttons, the types of operation modes, and the functions assigned in each operation mode are not limited to the above, and can be changed as appropriate.

  In FIG. 5 showing the electrical configuration of the digital camera 10, a lens motor 90 is connected to the imaging lens 16. An iris motor 94 is connected to the diaphragm 92. These motors 90 and 94 are stepping motors, which are controlled in operation by drive pulses transmitted from motor drivers 98 and 100 connected to the CPU 96, and perform photographing preparation processing when the release button 24 is half-pressed.

  The lens motor 90 moves the zoom lens of the imaging lens 16 to the wide side or the tele side in conjunction with the zoom operation. Further, the focus lens of the image pickup lens 16 is moved in accordance with zooming magnification of the zoom lens and the like, and the focus adjustment is performed so that the shooting conditions are optimized. The iris motor 94 operates the diaphragm 92 to adjust exposure.

  Behind the imaging lens 16 is a CCD 102 that captures a subject image that has passed through the imaging lens 16. A timing generator (TG) 104 controlled by the CPU 96 is connected to the CCD 102, and a shutter speed of the electronic shutter is determined by a timing signal (clock pulse) input from the TG 104.

  The imaging signal output from the CCD 102 is input to a correlated double sampling circuit (CDS) 106 and output as R, G, and B image data that accurately corresponds to the amount of charge accumulated in each pixel of the CCD 102. The image data output from the CDS 106 is amplified by an amplifier (AMP) 108 and converted to digital image data by an A / D converter (A / D) 110.

  The image input controller 112 is connected to the CPU 96 via the bus 114, and controls the CCD 102, the CDS 106, the AMP 108, and the A / D 110 in accordance with a control command from the CPU 96. Image data output from the A / D 110 is temporarily recorded in the SDRAM 115.

The AE detection circuit 116 calculates a photometric value (Ev) representing the brightness of the subject based on the image data stored in the SDRAM 115 based on the following equation, and outputs the calculated photometric value (Ev) to the CPU 96.
Ev = log ₂ (Σwi × 2 ^Evi / Σwi) −ΔEviso

  In the above equation, Evi is a photometric value for each area when an image based on the image data stored in the SDRAM 115 is divided into 64 areas as shown in FIG. wi is a weighting value set for each area, and is represented by a numerical value described in each area in the figure. The digital camera 10 employs a center-weighted metering method, and the weighting value is increased in the area closer to the center. ΔEviso is a photometric correction amount based on ISO200.

  Based on the photometric value (Ev) calculated in this way, exposure adjustment by the CPU 96 is performed. The setting of the area division and the weighting value in calculating the photometric value (Ev) is not limited to the above and can be changed as appropriate. In addition to the above-mentioned center-weighted metering method, there are a multi-segment metering method with different image segmentation methods and weighting methods, a spot metering method in which metering is performed only on a part of the image, and the like. However, any of these may be used.

  The image signal processing circuit 118 reads out image data from the SDRAM 115, performs various image processing such as gradation conversion, white balance correction, and γ correction processing, and records the image data in the SDRAM 115 again. The YC conversion processing circuit 120 reads the image data subjected to various processes by the image signal processing circuit 118 from the SDRAM 115 and converts it into a luminance signal Y and color difference signals Cr and Cb.

  The VRAM 122 is a memory for outputting a through image to the LCD 30, and stores image data that has passed through the image signal processing circuit 118 and the YC conversion processing circuit 120. Two frames of memories 122a and 122b are secured in the VRAM 122 so that image data can be written and read in parallel. The image data stored in the VRAM 122 is converted into an analog composite signal by the LCD driver 124 and displayed on the LCD 30 as a through image.

  The compression / decompression processing circuit 126 performs image compression on the image data YC converted by the YC conversion processing circuit 120 in a predetermined compression format (for example, JPEG format). The compressed image data is stored in the memory card 26 via the media controller 128.

  The CPU 96 is provided for overall control of the digital camera 10, and reads and controls various control programs and setting information recorded in the EEPROM 130 to the SDRAM 115, which is a working memory, and drives and controls the connected units. Control by the CPU 96 is performed based on the operation signals input from the release button 24, the mode selection button 22, the power button 20, and the operation buttons 41 to 49 of the operation unit 32 described above.

  The CPU 96 is provided with a function assignment table 132 and a display control unit 134. As shown in FIG. 7, the function assignment table 132 stores the correspondence between the contents of functions assigned to the operation buttons 41 to 49 (indicated as buttons A to I in the figure) and the operation mode of the digital camera 10. Has been. When an operation signal is input from each of the operation buttons 41 to 49, the CPU 96 checks the current operation mode and then refers to the function assignment table 132 to execute the function assigned to each of the operation buttons 41 to 49.

  In FIG. 8 which shows the drive mechanism of each operation button 41-49, the display control part 134 is connected to the drivers 71-79 which drive the display panels 61-69. The display control unit 134 controls these drivers 71 to 79 to display images on the display panels 61 to 69. The display control unit 134 checks the presence / absence of the assigned function and the type of function for each of the operation buttons 41 to 49 based on the current operation mode and the function assignment table 132. Then, a mark for explaining the assigned function is displayed on the display panel corresponding to the operation button.

  As shown in FIG. 9, in the shooting mode, the display control unit 134 displays a mark indicating a function for changing the zoom magnification on the display panels 61 and 62, and a mark indicating a function for shifting to the screen adjustment mode on the display panel 64. Is displayed, a mark indicating the function for shifting to the close-up mode is displayed on the display panel 65, a mark indicating the function for switching the strobe emission mode is displayed on the display panel 67, and the display panel 68 is shifted to the self-timer use mode. A mark indicating the function is displayed. At this time, the CPU 96 drives the LCD driver 124 to display a mark indicating that the current mode of the digital camera 10 is the photographing mode on the LCD 30.

  As shown in FIG. 10, in the playback mode, the display control unit 134 displays a mark representing a function for enlarging and reducing the playback image on the display panels 61 and 62, and causes the display panel 63 to shift to the print condition designation mode. A mark representing the function of erasing an image is displayed on the display panel 64, and a mark representing a function of moving the image forward and backward by one frame is displayed on the display panels 65 and 67. In the playback mode, the CPU 96 displays on the LCD 30 a mark indicating that the mode of the digital camera 10 is the playback mode.

  In the playback mode, when the playback image is enlarged larger than the screen of the LCD 30, the display control unit 134 has a function of moving the playback image up, down, left and right on the display panels 64, 65, 67, 68 as shown in FIG. Is displayed, and a mark representing a function for canceling the enlargement / reduction of the reproduced image is displayed on the display panel 69.

  As shown in FIG. 12, in the menu mode, the display control unit 134 causes the display panels 64, 65, 67, and 68 to display marks indicating the function of moving the cursor up, down, left and right, and selects the display panel 66 with the cursor. A mark representing a function for determining an item is displayed, and a mark representing a function for returning to the previous screen is displayed on the display panel 69. In the menu mode, the CPU 96 displays on the LCD 30 a mark indicating that the mode of the digital camera 10 is the menu mode.

  In FIG. 8, the display control unit 134 is provided with a brightness adjustment unit 136 that switches the brightness of the display panels 61 to 69. The brightness adjustment unit 136 is driven in two modes: an auto mode in which the brightness is automatically switched, and a manual mode in which the user sets the brightness. When the operation button 44 is operated in the photographing mode and the CPU 96 shifts to the screen adjustment mode, the CPU 96 displays a setting screen 140 shown in FIG.

  By moving the cursor 142 and selecting the tag 144 on the setting screen 140, the brightness adjustment unit 136 is driven in the auto mode. In the auto mode, the brightness adjustment unit 136 switches the brightness of the display panels 61 to 69 based on the photometric value (Ev) calculated by the AE detection circuit 116. The brightness of the display panels 61 to 69 can be switched in four stages, the darkest level 0 to the brightest level 3.

  The brightness adjustment unit 136 switches the brightness of the display panels 61 to 69 to level 0 when the photometric value (Ev) is less than 5 Ev. Further, the brightness adjustment unit 136 switches the brightness of the display panels 61 to 69 to level 1 when the photometric value (Ev) is 5 Ev or more and less than 9 Ev, and displays when the photometric value (Ev) is 9 Ev or more and less than 13 Ev. The brightness of the panels 61 to 69 is switched to level 2, and when the photometric value (Ev) is 13 Ev or more, the brightness of the display panels 61 to 69 is switched to level 3.

  It can be estimated that the larger the photometric value (Ev), the brighter the subject, that is, the brighter the periphery of the digital camera 10. For this reason, as described above, as the photometric value (Ev) increases, the brightness level of the display panels 61 to 69 is increased so that when the periphery of the digital camera 10 is bright, the display panels 61 to 69. Is bright and easy to see. Further, when the periphery of the digital camera 10 is dark, the brightness of the display panels 61 to 69 can be suppressed to reduce power consumption.

  On the other hand, by moving the cursor 142 on the setting screen 140 and selecting the tags 145, 146, 147, and 148, the brightness adjustment unit 136 is driven in the manual mode. When the tag 145 is selected, the brightness adjustment unit 136 switches the brightness of the display panels 61 to 69 to level 0. Further, the brightness adjustment unit 136 sets the brightness of the display panels 61 to 69 to level 1 when the tag 146 is selected, to level 2 when the tag 147 is selected, and to level 3 when the tag 148 is selected. Respectively. Providing the manual mode is convenient because the brightness of the display panels 61 to 69 can be switched according to the user's preference.

  In addition, as a method of switching the brightness of the display panel, a method of switching the brightness of the entire screen of the display panel or a screen portion 150 of the display panel other than the mark portion 152 and the mark as shown in FIG. The background portion 154 may be divided and at least one brightness may be switched. Any of these methods may be used. When the brightness is switched while distinguishing between the mark portion and the background portion, the brightness of the mark portion and the background portion may be determined so that the contrast of the screen increases as the brightness level increases.

  In the above embodiment, the AE detection circuit calculates the photometric value based on the image data obtained by the CCD, and the brightness of the display panel in the auto mode is determined according to the photometric value, so that the CCD is driven. If not, there is a concern that the brightness of the display panel cannot be determined in the auto mode. In order to prevent such a problem, the latest photometric value obtained by the AE detection circuit is stored in a storage unit such as SDRAM, and stored in the storage unit in modes other than the photographing mode. The brightness of the display panel may be determined based on the photometric value. Of course, the CCD may be driven periodically in modes other than the photographing mode to obtain photometric values. Further, instead of the CCD or AE detection circuit, a brightness detection sensor for detecting the brightness around the digital camera is provided, and display in the auto mode is performed according to the brightness around the digital camera obtained from the brightness detection sensor. The brightness of the panel may be determined.

  In the above embodiment, the digital camera has been described as an example, but the present invention is not limited to this. For example, the present invention may be applied to a mobile device other than a digital camera such as a mobile phone or a PDA (Personal Digital Assistance).

It is a front side external view of a digital camera. It is a back side top view of a digital camera. It is explanatory drawing showing the structure of an operation button. It is explanatory drawing showing the structure of a display panel. It is a block diagram of a digital camera. It is explanatory drawing showing the value of the weight for every divided area. It is explanatory drawing showing the correspondence of each operation mode and the function allocated to an operation button. It is a block diagram of the drive mechanism which drives an operation button. It is explanatory drawing showing an example of the display on a display panel. It is explanatory drawing showing an example of the display on a display panel. It is explanatory drawing showing an example of the display on a display panel. It is explanatory drawing showing an example of the display on a display panel. It is explanatory drawing showing the setting screen which sets the brightness of an operation button. It is explanatory drawing showing an example of the brightness control of a display panel.

Explanation of symbols

10 Digital camera 30 LCD
32 Operation part 41-49 Operation button 61-69 Display panel 71-79 Driver 96 CPU
116 AE detection circuit 132 function assignment table 134 display control unit 136 brightness adjustment unit 140 setting screen

Claims (5)

Operation buttons that change the function assigned according to the operation mode of the device,
Display means arranged on the surface of the operation button;
A brightness detection sensor that detects the brightness around the device;
And a display control unit configured to cause the display unit to display an image corresponding to the function assigned to the operation button and to switch the brightness of the image according to the brightness of the surroundings of the device. machine.   2. The portable device according to claim 1, further comprising an imaging unit that outputs an electric charge accumulated in each pixel as an imaging signal according to a subject light amount, and the imaging unit is also used as the brightness detection sensor. The image is composed of a character or mark portion explaining the function and a background portion,
The portable device according to claim 1 or 2, wherein the display control means switches the brightness of at least one of a character or mark portion and a background portion.   The portable device according to claim 1, further comprising an operation member for manually switching the brightness of the image.   5. A digital camera, comprising: an image sensor that outputs an imaging signal obtained by photoelectrically converting a subject image in the portable device according to claim 1;

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