JP4976770B2 - Display device, display method, program, and storage medium - Google Patents

Description

The present invention relates to a display device, a display method, a program, and a storage medium , and more particularly, to a display device, a display method, a program, and a storage medium using a display function for a backlight illumination type liquid crystal display element.

  Conventionally, as other light-emitting type liquid crystal display elements in display devices, a transmissive type using backlight illumination as a light source, a reflective type using external light as a light source, and semi-transmissive using both backlight illumination and external light as light sources The type is known. In the transmissive liquid crystal display element, the brightness of the backlight illumination greatly affects the display visibility. However, in the reflective or transflective liquid crystal display element, external light is used as a light source, so that the external illumination can be performed even in the absence of backlight illumination. If the light is bright to some extent, display visibility can be ensured.

  In addition, since the liquid crystal display element is extremely light and thin compared to a cathode ray tube, the liquid crystal display element is often used as a display device for portable home appliances such as a digital camera and a PDA. In such portable home appliances, batteries are used, so the continuous use time is limited. In particular, the power consumption of the backlight illumination is large. Therefore, when a minimum display visibility can be ensured, a technique for reducing the power consumption by turning off the backlight light source and improving the continuous use time has been performed (see Patent Document 1).

On the other hand, the display data displayed on the liquid crystal display element has become unique due to the large size, high resolution, and full color of the liquid crystal display element in recent years, and various expressions such as multi-tone color, increase in the number of characters used, colored icon display, etc. It is getting more.
JP 11-119322 A

  However, in the above conventional technique, display data of the same various expressions is displayed when the backlight illumination is turned on and off. Transflective and reflective liquid crystal display elements can maintain a certain level of brightness and color saturation by external light even when the backlight is turned off. However, when the backlight is turned off, the brightness and color saturation are reduced, and the display data is reproduced. The nature becomes low.

  Therefore, when display data of various expressions such as colored icon display is displayed on the liquid crystal display element when the backlight illumination is turned off, the visibility and display quality of the display data are deteriorated.

An object of the present invention is to provide a display device, a display method, a program, and a storage medium that can maintain visibility and display quality even when backlight illumination is turned off.

In order to achieve the above object, a display device of the present invention is a display device including display means for displaying display data and illumination means for illuminating the display means, so that the illumination means is at least turned on or off. Control means for controlling the display means, and display control means for controlling the display means to display first display data when the illumination means is turned on and to display second display data when the illumination means is turned off. wherein the second display data, the less number of gradations than the first display data, Ri Oh display data difference in luminance is large between the background color and the character, the second display data, the reduces the number of items displayed than 1 of the display data, characterized that you have been added description character items.
In order to achieve the above-described object, the display method of the present invention includes a display step of displaying display data on a display means, an illumination step of illuminating the display means with illumination means, and at least lighting or lighting the illumination means. Control step for controlling to turn off, and display control for controlling the display means to display first display data when the lighting means is turned on and to display second display data when the lighting means is turned off. and a step, the second display data, the less number of gradations than the first display data, Ri Oh display data difference in luminance is large between the background color and the character, the second display data , the reduces the number of items displayed than 1 of the display data, it characterized that you have been added description character items.

According to the present invention, the state of the illumination unit is controlled, and display data to be displayed on the liquid crystal display unit is generated according to the state of the illumination unit, so that visibility and display quality can be maintained even when the backlight illumination is turned off. Can do.

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

  FIG. 1 is a block diagram showing an internal configuration of a display device according to an embodiment of the present invention.

  In FIG. 1, a display device 15 includes a system control circuit 1, a power switch 2, a power supply unit 3, a battery 4, an operation member 5, a timer control unit 6, an image display processing unit 7, a liquid crystal drive circuit 8, and a liquid crystal panel display element. 9 is provided. The display device 15 includes an illumination brightness changing circuit 10, a backlight illumination 11, a RAM control circuit 12, a RAM 13, and a nonvolatile memory 14.

  The system control circuit 1 is composed of a central processing processor and controls the entire display device 15. The power switch 2 switches the power on / off of the display device 15. The power supply unit 3 generates various power supplies to be supplied to the entire display device 15. Further, the power supply unit 3 can perform power-on control independently of the system control circuit 15 according to the supply destination block. That is, the power supply unit 3 can perform power saving control by appropriately controlling the power supply for blocks that do not need to operate constantly.

  The display device 15 is assumed to be portable, and as the battery 4, a primary battery such as an alkaline battery, a nickel hydride rechargeable battery, or the like can be used. The system control circuit 15 detects the remaining battery level of the battery 4 from the power supply unit 3 and displays the battery replacement time on the liquid crystal panel display element 9.

  The operation member 5 is various operation members for operating the display device 15. The operation member 5 has a mode setting dial for switching the operation state of the display device 15, a menu button for displaying a menu capable of selecting a detailed setting, and for selecting / cancelling each item in the screen during the menu display. Includes selection operation keys. The operation member 5 also includes a determination button, a cancel button, a sleep button for forcibly shifting to the sleep mode, and the like.

  The timer control unit 6 has a clock function, a calendar function, a timer counter function, and an alarm function, and is used for system management such as a transition time to the sleep mode and alarm notification.

  The image display processing unit 7 is an arithmetic processing circuit for converting the display data stored in the image display area assigned to the RAM 13 into a data format that can be displayed on the liquid crystal driving circuit 8. The dot clock signal is output. The image display processing unit 7 also has a contrast change function for performing gain correction on the luminance signal of the display data, an error diffusion calculation process for the pixels of the display data, and a color gradation change function for performing a quantization process after the dither calculation process Have Furthermore, the image display processing unit 7 combines a sprite function for displaying characters and icons in arbitrary positions with the background image data, an enlargement / reduction function for arbitrarily increasing the size of characters and icons, and the character and icon colors arbitrarily. It has a changeable color palette change function.

  The liquid crystal drive circuit 8 generates and supplies RGB independent output signals, drive timing signals, and power for driving the liquid crystal display panel element 9 based on the signal input from the image display processing unit 7. Further, the liquid crystal drive circuit 8 controls the matrix conversion table, picture correction, bright correction, contrast correction, γ correction, left / right up / down inverted display control for the display data of the image display processing unit 7 according to the communication setting of the system control circuit 1. And display position adjustment.

  The liquid crystal display panel element 9 uses a thin film transistor active matrix driving system. The liquid crystal display panel element 9 uses a transmission method, a semi-transmission method, a reflection method, or the like as an illumination method.

  The illumination brightness changing circuit 10 adjusts the illumination brightness of the backlight illumination 11 in a stepwise manner. That is, the illumination brightness changing circuit 10 linearly changes the illumination brightness by limiting the current flowing through the light emitter of the backlight illumination 11 by voltage driving, PWM driving, or the like from the system control circuit 1.

  The backlight illumination 11 is fixed to the back surface of the liquid crystal panel display element 9, and is composed of an LED, a fluorescent tube, or the like. Further, the backlight illumination 11 projects light from the back surface of the liquid crystal panel display element 9, and the light transmittance changes according to the voltage applied to each pixel of the liquid crystal panel display element 9, and passes through the RGB color filter. And color reproduction is possible.

  The RAM control circuit 12 performs data transfer control among the system control circuit 1, the image display processing unit 7, and the RAM 13. The RAM control circuit 12 has a direct memory access control function so that high-speed transfer is possible, and can directly transfer display data to the image display processing unit 7 without using the system control circuit 1.

  The RAM 13 is a high-speed volatile memory, and a program stack area, a status storage area, a calculation area, a work area, and an image display data area of the system control circuit 1 are secured. In some cases, the first display data and the second display data in the present invention are assigned for temporary work.

  The nonvolatile memory 14 is configured by an electrically erasable / recordable nonvolatile memory such as a flash memory. The nonvolatile memory 14 stores menu setting information for the display device 15 and a control program. The nonvolatile memory 14 stores data necessary for composing display image data such as character font data, icon data, menu items, menu backgrounds, and color palette information. A program for causing the system control circuit 1 to execute the processing of FIG. 2 or FIG. 3 described later is stored in the nonvolatile memory 14.

  FIG. 2 is a flowchart of the liquid crystal display control process executed by the system control circuit 1 in FIG.

  In FIG. 2, the system control circuit 1 acquires the state of the operation member 5 and the timer control unit 6 in the sleep mode when shifting to the present process. Based on these states, it is determined whether or not there is a display start request to the liquid crystal panel display element 9 in the lighting mode of the backlight illumination 11 (step S1). As a result of the determination, when there is a display start request to the liquid crystal panel display element 9 in the lighting mode of the backlight illumination 11, the process proceeds to step S2. On the other hand, when there is no display start request to the liquid crystal panel display element 9 in the lighting mode of the backlight illumination 11, the process proceeds to step S7.

  In step S <b> 2, the system control circuit 1 generates first display data for displaying an image while the backlight illumination 11 is turned on. The first display data is generated based on display data prepared in advance in the nonvolatile memory 14.

  Next, the system control circuit 1 transfers the first display data generated in step S2 to the image display area of the RAM 13 (step S3).

  Next, the system control circuit 1 performs image display processing setting (step S4). That is, the system control circuit 1 performs register setting of the image display processing unit 7 and starts outputting display data signals to the liquid crystal driving circuit 8.

  Next, the system control circuit 1 sends a drive start command for the liquid crystal panel display element 9 to the liquid crystal drive circuit 8 by communication to start driving the liquid crystal panel display element 9 (step S5). The liquid crystal drive circuit 8 starts outputting a drive signal to the liquid crystal panel display element 9 after a predetermined output stabilization period has elapsed after receiving the drive start command from the system control circuit 1.

  Next, the system control circuit 1 sets an appropriate luminance for the illumination luminance changing unit 10 to turn on the backlight illumination 11 (step S6), and ends this processing. Thereby, the liquid crystal panel display element 9 performs display using the first display data.

  In step S7, based on the state acquired in step S1, it is determined whether or not there is a display start request to the liquid crystal panel display element 9 in the extinguishing mode of the backlight illumination 11. As a result of the determination, when there is a display start request to the liquid crystal panel display element 9 in the off mode of the backlight illumination 11, the process proceeds to step S8. On the other hand, when there is no display start request to the liquid crystal panel display element 9 in the extinguishing mode of the backlight illumination 11, it is determined that it is a display stop request to the liquid crystal panel display element 9, and the process proceeds to step S13.

  In step S8, the system control circuit 1 generates second display data for displaying an image while the backlight illumination 11 is turned off. The second display data is based on the first display data and the conversion information prepared in advance in the nonvolatile memory 14, and the character icon color palette changing function, contrast changing function, and color gradation changing function of the image display processing unit 7 It is generated by a character icon enlargement function or the like.

  Next, the system control circuit 1 transfers the second display data generated in step S8 to the image display area of the RAM 13 (step S9).

  Next, the system control circuit 1 performs image display processing setting (step S10). That is, the system control circuit 1 performs register setting of the image display processing unit 7 and starts outputting display data signals to the liquid crystal driving circuit 8.

  Next, the system control circuit 1 sends a drive start command for the liquid crystal panel display element 9 to the liquid crystal drive circuit 8 by communication to start driving the liquid crystal panel display element 9 (step S11). The liquid crystal drive circuit 8 starts outputting a drive signal to the liquid crystal panel display element 9 after a predetermined output stabilization period has elapsed after receiving the drive start command from the system control circuit 1.

  Next, the system control circuit 1 executes setting for turning off the backlight illumination 11 to the illumination brightness changing unit 10 to turn off the backlight illumination 11 (step S12), and ends this processing. Thereby, the display by the second display data is performed on the liquid crystal panel display element 9.

  In step S <b> 13, the system control circuit 1 executes setting for turning off the backlight illumination 11 to the illumination luminance changing unit 10 to turn off the backlight illumination 11.

  Next, the system control circuit 1 sends a drive stop command for the liquid crystal panel display element 9 to the liquid crystal drive circuit 8 by communication to stop driving the liquid crystal panel display element 9 (step S14). The liquid crystal drive circuit 8 stops outputting the drive signal to the liquid crystal panel display element 9 immediately after receiving the drive stop command from the system control circuit 1.

  Next, the system control circuit 1 cancels the image display processing setting (step S15), and ends this processing. That is, the system control circuit 1 sets the register of the image display processing unit 7 and stops outputting the display data signal to the liquid crystal driving circuit 8. As a result, nothing is displayed on the liquid crystal panel display element 9.

  According to the processing of FIG. 2, when there is a display start request to the liquid crystal panel display element 9 in the off mode of the backlight illumination 11 (YES in step S7), the system control circuit 1 turns off the backlight illumination 11. Second display data for displaying an image inside is generated. Thereby, visibility and display quality can be maintained even when the backlight illumination 11 is turned off.

  FIG. 3 is a flowchart of a modification of the liquid crystal display control process of FIG.

  In this process, display data corresponding to a change in the brightness level of the backlight illumination 11 is generated.

  In FIG. 3, the system control circuit 1 acquires the state of the operation member 5 when shifting to this processing. Based on this state, it is determined whether or not there is a display start request to the liquid crystal panel display element 9 (step S20).

  As a result of this determination, when there is a display start request to the liquid crystal panel display element 9, the process proceeds to step S21. On the other hand, when there is a display stop request to the liquid crystal panel display element 9, the process proceeds to step S27.

  In step S21, the system control circuit 1 sets an appropriate luminance for the illumination luminance change circuit 10 based on the illumination luminance setting information that is arbitrarily set by menu setting or the like, or automatically set, and the backlight. The brightness of the illumination 11 is set. In the illumination brightness setting information, the lowest setting state may be turned off.

  Next, display data corresponding to the luminance set in step S21 is generated (step S22). That is, the system control circuit 1 uses the brightness → display data conversion information prepared in advance in the nonvolatile memory 14 to change the character icon color palette, the contrast change function, the color gradation change function, the character icon of the image display processing unit 7. Display data is generated by an enlargement function of the.

  Next, the system control circuit 1 transfers the display data generated in step S22 to the image display area of the RAM 13 (step S23).

  Next, the system control circuit 1 performs image display setting (step S24). That is, the system control circuit 1 performs register setting of the image display processing unit 7 and starts outputting display data signals to the liquid crystal driving circuit 8.

  Next, the system control circuit 1 sends a drive start command for the liquid crystal panel display element 9 to the liquid crystal drive circuit 8 by communication to start driving the liquid crystal panel display element 9 (step S25). The liquid crystal drive circuit 8 starts outputting a drive signal to the liquid crystal panel display element 9 after a predetermined output stabilization period has elapsed after receiving the drive start command from the system control circuit 1.

  Next, the system control circuit 1 turns on the backlight 11 with the brightness set for the illumination brightness changing unit 10 (step S26), and ends this process. As a result, the liquid crystal panel display element 9 performs display using display data corresponding to the luminance of the backlight illumination 11.

  In step S <b> 27, the system control circuit 1 executes setting for turning off the backlight illumination 11 to the illumination luminance changing unit 10 to turn off the backlight illumination 11.

  Next, the system control circuit 1 sends a drive stop command for the liquid crystal panel display element 9 to the liquid crystal drive circuit 8 by communication to stop driving the liquid crystal panel display element 9 (step S28). The liquid crystal drive circuit 8 stops outputting the drive signal to the liquid crystal panel display element 9 immediately after receiving the drive stop command from the system control circuit 1.

  Next, the system control circuit 1 cancels the image display processing setting (step S29), and ends this processing. That is, the system control circuit 1 sets the register of the image display processing unit 7 and stops outputting the display data signal to the liquid crystal driving circuit 8. As a result, nothing is displayed on the liquid crystal panel display element 9.

  According to the process of FIG. 3, since display data corresponding to the set brightness is generated (step S22), visibility and display quality can be maintained even when the backlight illumination 11 is turned off.

  Note that the display device 15 according to the present embodiment may be used as a display device such as an electronic imaging device.

  FIG. 4 is a block diagram showing a configuration of an electronic imaging apparatus having a display device according to the second embodiment of the present invention.

  In FIG. 4, a lens unit 200 and a strobe unit 300 are connected to the electronic imaging apparatus 100.

  The lens unit 200 includes a lens interface 201, a lens mount 202, a lens control circuit 203, a lens 210, and a diaphragm 211.

  The strobe unit 300 includes an accessory shoe connection unit 301 and a strobe light emission control circuit 302.

  The electronic imaging apparatus 100 includes a lens interface 101, a lens mount 102, an accessory shoe 111, a system control circuit 120, an image sensor 121, an A / D conversion unit 122, an image processing circuit 123, a memory control circuit 124, and a liquid crystal panel display unit. 125.

  The electronic imaging apparatus 100 also includes a backlight 126, a memory 127, an external removable memory 128, a nonvolatile memory 129, a power circuit 130, a playback switch 131, a menu switch 132, a mode dial 133, and a release switch 134.

  The electronic imaging apparatus 100 further includes various operation members 135, a power switch 136, a camera control circuit 140, a shutter control unit 141, a photometry unit 142, a distance measurement unit 143, and a shutter 144.

  The image sensor 121 converts an optical image of a subject formed through the lens 210, the aperture 211, the lens mounts 205 and 105, and the shutter 144 into an electrical signal. The A / D converter 122 converts the analog signal output from the image sensor 121 into a digital signal. The converted digital signal is controlled by the memory control circuit 124 and the system control circuit 120 and stored in the memory 127.

  The image processing circuit 123 performs predetermined pixel interpolation processing and color conversion processing on the digital signal data or the data from the memory control circuit 124. The image processing circuit 123 also includes a compression / decompression circuit that compresses and decompresses image data by adaptive discrete cosine transform (ADCT) or the like, reads an image stored in the memory 127, performs compression processing or decompression processing, The processed data is written into the memory 127. Further, the image processing circuit 123 performs predetermined arithmetic processing using the captured image data, and performs TTL AWB (auto white balance) processing based on the obtained arithmetic result. Further, the image processing circuit 123 has a contrast changing function for performing gain correction on the luminance signal, a color gradation changing function for performing an error diffusion calculation process on the pixel, and a quantization process after the dither calculation process. In addition, the image processing circuit 123 is a sprite function that combines and displays characters and icons at an arbitrary position with background image data, an enlargement / reduction function that arbitrarily enlarges characters and icons, and arbitrarily changes the color of characters and icons. Possible color palette change function.

  The memory control circuit 124 controls data transmission / reception among the A / D conversion unit 122, the image processing circuit 123, the liquid crystal panel display unit 125, the external removable memory 128, and the memory 127. The data of the A / D converter 122 is written into the memory 127 via the image processing circuit 123 and the memory control circuit 124, or the data of the A / D converter 122 is directly passed through the memory control circuit 124.

  The liquid crystal panel display unit 125 displays a new screen or an image file stored in the external removable memory unit 128 written in the display data storage area of the memory 127.

  The backlight illumination 126 is backside illumination for the liquid crystal panel display unit 125. Examples of the light source element of the backlight illumination 126 include an LED, an organic EL, and a fluorescent tube. The backlight illumination 126 can be arbitrarily turned on or off according to an instruction from the system control circuit 120. When the backlight illumination 126 is turned off, the power consumption of the electronic imaging apparatus 100 can be significantly reduced. Further, the backlight illumination 126 has a dimming function for adjusting the luminance by limiting the energization current of the light source element by either the voltage driving method or the PWM driving method by the system control circuit 120.

  The memory 127 stores captured still images and images for playback display. The memory 127 has a storage capacity sufficient to store a predetermined number of still images. The memory 127 can also be used as a work area for the system control circuit 120 and a work area for display data conversion.

  The external detachable memory unit 128 performs image file recording and reading on a recording medium such as a compact flash (registered trademark) or an SD card.

  The nonvolatile memory 129 can be electrically erased and recorded, and for example, a flash memory or an EEPROM is used. The nonvolatile memory 129 stores a program for saving the shooting state and controlling the electronic imaging apparatus 100.

  The power supply circuit 130 includes a battery detection circuit, a DC-DC converter, a switch circuit that switches a block to be energized, and the like. Further, the power supply circuit 130 detects the presence / absence of a battery, the type of battery, and the remaining battery level, controls the DC-DC converter based on the detection result and the instruction of the system control circuit 120, and requires a necessary voltage. It is supplied to each block unit for a short period.

  The system control circuit 120 performs power management control for power saving by stopping power supply to unnecessary blocks in accordance with the operation state of the electronic imaging apparatus 100. For example, the system control circuit 120 does not need to operate the camera control block in the case of image reproduction display or menu screen display, so the camera control circuit 140, photometry unit 142, distance measurement unit 143, image sensor 121, lens unit 200, strobe unit The power supply to 300 is cut off.

  The shutter control unit 141 controls the shutter 144 based on the photometric information from the photometric unit 142 in cooperation with the lens control circuit 203 that controls the aperture 211.

  The photometry unit 142 performs AE (automatic exposure) processing. The photometric unit 142 causes the light beam incident on the lens 210 to enter the photometric unit 142 via the stop 211, the lens mounts 202 and 102, and a photometric lens (not shown), and thereby the image formed as an optical image. The exposure state can be measured. The photometry unit 142 also has an EF (flash dimming) processing function in cooperation with the strobe unit 200. The strobe unit 200 has an AF auxiliary light projecting function and a flash light control function.

  The distance measuring unit 143 performs AF (autofocus) processing. The distance measuring unit 143 forms an optical image by causing the light beam incident on the lens 210 to enter the distance measuring unit 143 via the aperture 211, the lens mounts 202 and 102, and a distance measuring mirror (not shown). Measure the in-focus state of the image. In addition, since the electronic imaging device 100 is configured to include the distance measurement unit 143 and the photometry unit 142, the AF (auto focus) process, the AE (automatic exposure) process, Each process of the EF (flash dimming) process is performed.

  The camera control circuit 140 controls a series of operations as a camera by transmission / reception communication with the shutter control unit 141, the photometry unit 142, and the distance measurement unit 143. The camera control circuit 140 controls the lens unit 200 and the strobe unit 300.

  The system control circuit 120 controls the entire electronic imaging apparatus 100. The operation members 131, 132, 133, 134, 135, 136 are used for inputting various operation instructions of the system control circuit 120. These operation members are composed of one or a plurality of combinations such as a switch, a dial, a touch panel, pointing by line-of-sight detection, and a voice recognition device.

  The reproduction switch 131 is used for a reproduction display mode operation for displaying predetermined image data on the liquid crystal display panel unit 125. When the image file stored in the external detachable memory unit 128 is reproduced and displayed, the reproduction switch 131 must be operated. If the playback switch 131 is already operated in the playback display mode, the playback display mode can be switched to the shooting mode.

  The menu switch 132 is used to display a list of various items on the liquid crystal display panel unit 125. The display contents of the various item lists include state settings related to shooting, recording medium format, clock settings, development parameter settings, and user function settings (custom function settings).

  The mode dial 133 is used to switch and set each function shooting mode. Each function shooting mode includes an automatic shooting mode, a program shooting mode, a shutter speed priority shooting mode, an aperture priority shooting mode, a manual shooting mode, a portrait shooting mode, a landscape shooting mode, a sports shooting mode, a night scene shooting mode, and the like.

  The release switch 134 is a switch that is turned ON when the release button is being operated (SW1) and when the operation is completed (SW2). The release switch 134 instructs the start of operations such as AF (autofocus) processing, AE (automatic exposure) processing, AWB (auto white balance) processing, and EF (flash dimming) processing in the middle of operation. The release switch 134 instructs the start of a series of processes including exposure processing, development processing, and recording processing when the operation is completed.

  The various operation members 135 are operation units including various switches. The various operation members 135 include, for example, shooting mode, continuous shooting mode, set, macro, page feed, page return, flash setting, menu movement + (plus), menu movement-(minus), white balance selection, shooting image quality selection, Including exposure compensation and other operation members. Further, the various operation members 135 set date / time setting, zoom magnification + for changing zoom magnification for image reproduction enlargement / reduction, zoom magnification-, up / down / left / right switch, and ON / OFF of the liquid crystal panel display unit 125. Includes image display ON / OFF switch. Further, the various operation members 135 include a quick review ON / OFF switch, a compression mode switch, an image deletion switch, an AF mode setting switch that can set a one-shot AF mode and a servo AF mode, and the like.

  Further, the functions of the plus button and the minus button can be selected more easily by providing a rotary dial switch and a cross key.

  The power switch 136 is used to switch and set the power-on and power-off modes of the electronic imaging apparatus 100. The power switch 136 is also used to set the power on and power off of various attached devices such as the lens unit 200, the strobe unit 300, and the recording medium connected to the electronic imaging apparatus 100.

  The lens mounts 102 and 202 are interfaces for connecting the electronic imaging apparatus 100 to the lens unit 200. The lens interfaces 101 and 201 are connectors that electrically connect the electronic imaging apparatus 100 to the lens unit 200, and are controlled by the camera control circuit 140.

  The accessory shoe 111 and the accessory shoe connection unit 301 are interfaces for connecting the electronic imaging apparatus 100 to the strobe unit 300.

  The lens unit 200 guides an optical image of a subject (not shown) from the lens 210 through the aperture 211, the lens mounts 202 and 102, and the shutter 144, and forms an image on the image sensor 121.

  The lens control circuit 203 controls the entire lens unit 200. The lens control circuit 203 is a memory for storing operation constants, variables, programs, etc., identification information such as numbers unique to the lens unit 200, management information, function information such as an open aperture value, minimum aperture value, focal length, And a function of a nonvolatile memory for holding past setting values and the like. The lens control circuit 203 has functions for controlling the aperture 211, controlling the focusing of the photographing lens 210, and controlling zooming of the photographing lens 210.

  The strobe unit 300 is connected to the accessory shoe 111. The strobe light emission control circuit 302 controls the entire strobe unit 300 and controls a light emission amount and a light emission timing for a light emission unit such as a xenon lamp (not shown) based on information from the photometry unit 142.

  The accessory shoe connection unit 301 is an interface that electrically connects the strobe unit 300 and the electronic imaging device 100 in the accessory shoe 111.

  5 and 6 are flowcharts of control processing executed by the system control circuit 120 in FIG.

  5 and 6, the system control circuit 120 performs a predetermined initial setting by turning on the power supply such as battery replacement (step S100). That is, the camera control circuit 140 and the system control circuit 120 initialize flags and control variables. When a recording medium (not shown) (such as a memory card) is detected by the external removable memory unit 128, initial settings such as acquisition of file information in the memory card and registration of interrupt processing are performed.

  Next, the system control circuit 120 determines the set position of the power switch 136. If the power switch 136 is ON (YES in step S101), the system control circuit 120 proceeds to step S102.

  In step S <b> 102, the system control circuit 120 activates a power management system that monitors the remaining amount of power (not shown) and the operation status, which are configured by a DC / DC converter, a battery, and the like in the power circuit 130.

  Next, it is determined whether or not there is a remaining battery level sufficient to activate the electronic imaging apparatus 100 or a voltage supplied by the power supply circuit 130 (step S103). As a result of the determination, if there is a sufficient remaining battery level or voltage, the process proceeds to step S104. On the other hand, if there is not enough battery power or voltage, an error information flag is set in the memory in the system control circuit 120 and the process proceeds to step S127.

  In step S104, the camera control circuit 140 detects the lens unit 200, the strobe unit 300, and the like that are currently mounted on the electronic imaging apparatus 100, acquires information about each accessory, and executes initial settings. In addition, the camera control circuit 140 acquires information on the setting position of the mode dial from the system control circuit 120 and setting information related to the shooting mode stored in the nonvolatile memory 129. Further, the camera control circuit 140 performs appropriate photographing condition setting processing from the setting information of the photometry unit 142, the distance measurement unit 143, and each detected accessory. In addition, the system control circuit 120 generates information on the photographing conditions set in step S104 as display data, and performs display processing on the liquid crystal display panel unit 125. Further, the luminance setting of the backlight illumination unit 126 is performed based on the luminance setting information that is preset in the menu mode (step S119) and stored in the nonvolatile memory 129.

  Next, the system control circuit 120 performs initial setting of a timer function in a system control circuit (not shown) (step S105). With this timer function, when none of the operation members 131, 132, 133, 134, 135, and 136 set in the electronic imaging device 100 for a certain period is pressed, the power saving standby processing ( (Sleep mode).

  Next, the system control circuit 120 determines whether or not there is a sufficient battery level to activate the electronic imaging apparatus 100 (step S111). If the result of this determination is that there is a sufficient remaining battery level, the routine proceeds to step S112. On the other hand, when there is not enough remaining battery power, an error information flag is set in the memory in the system control circuit 120, and the process proceeds to step S127.

  In step S127, the content of the error information flag is determined, and a predetermined warning display using an image or sound is performed using the liquid crystal panel display unit 125. Next, the setting position of the power switch 136 is determined. If the power switch 136 is OFF (YES in step S128), the process proceeds to step S125.

  In step S112, the system control circuit 120 determines whether or not the setting position of the mode dial 133 has been changed. If the setting position of the mode dial 133 is changed as a result of this determination, the camera control circuit 140 is notified of the current shooting conditions. The camera control circuit 140 executes shooting condition setting processing from the notified shooting mode information, updates the display of the current shooting conditions on the liquid crystal panel display unit 125 (step S113), and returns to step S111.

  If the result of determination in step S112 is that the setting position of the mode dial 133 has not been changed, the process proceeds to step S114.

  In step S114, the system control circuit 120 determines whether or not the release switch 134 (SW1) has been pressed. If the release switch 134 (SW1) is pressed as a result of this determination, a series of release processes of AF / AE, exposure, development, and recording are executed (step S115), and the process returns to step S111.

  If the result of determination in step S114 is that release switch 134 (SW1) has not been pressed, processing proceeds to step S116.

  In step S116, the system control circuit 120 determines whether or not the regeneration switch 131 has been pressed. If the reproduction switch 131 is pressed as a result of this determination, the captured image is reproduced and displayed by the liquid crystal display panel unit 125 by the reproduction mode process (step S117), and the process returns to step S111. The processing in step S117 also includes processing such as page advance / return of the reproduced image by various operation members 135, simultaneous display of nine screens (multi-reproduction), enlarged display, shooting condition display (INFO reproduction), and deletion of the shot image. included.

  If the result of determination in step S116 is that the playback switch 131 has not been pressed, processing proceeds to step S118.

  In step S118, the system control circuit 120 determines whether the menu switch 132 has been pressed. As a result of the determination, when the menu switch 132 is pressed, the process proceeds to step S119.

  In step S119, the liquid crystal panel display unit 125 displays various items such as auxiliary settings for various camera photographing and utilities to the recording medium, and selection and execution are performed by various operation members of the various operation members 135 (step S119). Return to step S111. The menu mode setting items include a luminance setting item for the backlight illumination 126 and a display data switching function valid / invalid setting item corresponding to the backlight illumination.

  If the result of determination in step S118 is that the menu switch 132 has not been pressed, processing proceeds to step S120.

  In step S120, the system control circuit 120 determines whether any switch of the various operation members 135 has been pressed. As a result of the determination, when any switch of the various operation members 135 is pressed, processing corresponding to the various operation members is executed (step S121), and the process returns to step S111.

  As a result of the determination in step S120, when any switch of the various operation members 135 is not pressed, the process proceeds to step S122.

  In step S122, the system control circuit 120 determines whether or not a predetermined time has elapsed since the initialization of the timer function in step S105. As a result of the determination, when a predetermined time has elapsed, a sleep mode process of FIG. 7 described later is executed (step S123), and the process returns to step S111.

  As a result of the determination in step S122, if the predetermined time has not elapsed since the timer function was initialized in step S105, the process proceeds to step S124. Note that the timer function is always cleared when any one of the above-described steps S113, S115, S117, S119, or S121 is executed.

  In step S124, the system control circuit 120 determines the set position of the power switch 136 and determines whether or not the power switch 136 is ON (step S101). If the result of this determination is that the power switch 136 is ON, processing returns to step S111. On the other hand, when the power switch 136 is OFF, the process proceeds to step S125.

  In step S125, status saving processing is performed. That is, in order to perform the termination processing of the electronic imaging apparatus 100, necessary parameters, setting values, shooting modes, and the like including flags and control variables are recorded in the nonvolatile memory 129, the memory in the system control circuit 120, and the like.

  Next, the power supply circuit 130 cuts off unnecessary power sources for the respective parts of the electronic imaging apparatus 100 including the liquid crystal panel display unit 125, the external removable memory 128, the lens unit 200, and the strobe unit 300. Further, the system control circuit 120 ends the power management system that monitors the operation status (step S126), and returns to step S101.

  FIG. 7 is a flowchart of the sleep mode process in step S123 of FIG.

  In FIG. 7, the system control circuit 120 generates sleep mode display data for the existing display data generated in any of step S104, step S113, step S117, step S119, or step S121 ( Step S131). Here, the display data generation processing table for the backlight illumination extinction mode prepared in advance in the nonvolatile memory 129 is referred to, and the image processing circuit 123 is sequentially required as necessary from the existing display data stored in the memory 127. Execute the process. The processed display data is stored in a display data generation temporary work area prepared in the memory 127. After executing all the processing, the display data is transferred from the temporary work area of the memory 127 to the image display data storage area by the memory control circuit 124. Further, a contrast change process for performing gain correction on the luminance signal, an error diffusion calculation process on the pixel, a dither calculation process, a color gradation change process for performing a quantization process, and the like are performed. Further, enlargement / reduction processing for changing characters and icons to an arbitrary size, color palette changing processing for arbitrarily changing characters and icons, and the like are performed.

  Next, the system control circuit 120 performs image display processing setting for starting image display on the image processing circuit 123 and the liquid crystal panel display unit 125 (step S132). Thereby, the display data for the sleep mode generated in step S131 is output to the display panel element of the liquid crystal display panel unit 125.

  Next, the system control circuit 120 turns off the backlight illumination unit 126 (step S133). The current consumption can be significantly reduced by turning off the backlight illumination.

  Next, the system control circuit 120 issues a standby command to the camera control circuit 140. As a result, processing other than the image processing circuit 123, the image display processing of the liquid crystal panel display unit 125, and the various switch detection processing of the operation members 131, 132, 133, 134, or 135 for releasing the sleep mode is interrupted. Further, the operation clock frequency is switched to the low speed, and the mode is shifted to the low speed operation mode (step S134). Thereby, the current consumption of the system control circuit 120 itself is reduced.

  Next, the system control circuit 120 stops supplying power to unnecessary blocks of the power supply circuit 130 (step S135), and proceeds to step S136.

  In step S136, the system control circuit 120 determines whether any of the various switches set to wake up for canceling the sleep mode has been pressed. If any of the various switches set to wake up is pressed as a result of this determination, the process proceeds to step S138, and the wake up operation is sequentially executed. On the other hand, when any of the various switches set to wake up is not pressed, the process proceeds to step S137.

  In step S137, it is determined whether the remaining battery level is sufficient. If the remaining battery level is not sufficient, an error information flag is set in the memory in the system control circuit 120, and the process proceeds to step S127. On the other hand, when the remaining battery level is sufficient, the process returns to step S136.

  In step S138, the power supply to each block stopped in step S135 is resumed. Next, the system control circuit 120 issues an operation state command to the camera control circuit 140, switches the operation clock frequency to high speed, shifts to the high speed operation mode, and resumes predetermined processing (step S139).

  In step S140, the system control circuit 120 displays the display data for the standard mode corresponding to the luminance when the backlight illumination 126 is turned on, with respect to the display data in the backlight illumination extinction mode stored in the memory 127 in step S131. Is generated. The display data for the standard mode is transferred to a predetermined image display storage area in the memory 127. In step S131, the display data storage area of the memory 127 may be secured for the existing display data. Thus, the processing time can be shortened by performing the transfer process from the display data storage area to the image display storage area without generating the display data for the standard mode.

  Next, the system control circuit 120 performs image display processing setting for starting image display on the image processing circuit 123 and the liquid crystal panel display unit 125 (step S141). As a result, the display data for the standard mode generated in step S140 is output to the display panel element of the liquid crystal display panel unit 125.

  Next, the system control circuit 120 performs a lighting process on the backlight illumination unit 126 (step S142), ends the process, and returns to step S111. Note that the luminance when the backlight illumination 126 is turned on is the luminance set before the transition to the sleep mode.

  According to the process of FIG. 7, display data for the sleep mode is generated (step S131), so visibility and display quality can be maintained even when the backlight illumination 126 is turned off.

  8A and 8B are diagrams showing display data of photographing conditions in the electronic imaging apparatus 100 of FIG. 4. FIG. 8A shows when the backlight illumination 126 is turned on, and FIG. 8B shows when the backlight illumination 126 is turned off. .

  In FIG. 8A, the display data 400 for the standard mode is displayed on the liquid crystal panel display unit 125 in the shooting condition setting process in step S104 of FIG. 5 or step S113 of FIG.

  The display data 400 includes setting information 401 for the shutter 144 and the aperture 211, shooting ISO sensitivity information 402, remaining battery information 403 determined by the power supply unit 130, setting information 404 such as recording image quality, white balance, and red-eye reduction function. . Further, the display data 400 includes an exposure meter 411 determined based on a photometric mode condition selected based on photometric mode information 405 for determining exposure, and information acquired by the camera control circuit 140 from the photometric unit 142, an external removable memory unit 128 includes information 406 that can be recorded on a recording medium such as a CF card attached to 128.

  The display data 400 is used to display current date / time information 407, white balance bracket shooting setting information 408, reference parameter setting information 409 at the time of white balance calculation, and a shot image after shooting on the liquid crystal panel display unit 125. The setting information 410 is included.

  The display data 400 uses multi-tone colors, uses a large number of characters, and has a rich expression structure. In addition, since the display data 400 has a small difference in luminance between characters and background color and has low contrast, it is difficult to read characters and icons when the backlight illumination is turned off and the display is continued.

  In FIG. 8B, the display data 500 for the sleep mode is displayed on the liquid crystal panel display unit 125 in the sleep mode process of FIG. 7 that is the sleep mode operation of the electronic imaging apparatus 100.

  The display data 500 has a configuration in which display items are significantly reduced compared to the display data 400. In the display data 500, the setting information 501 of the shutter 144 and the aperture 211, the battery remaining amount information 502, the number of recordable sheets 503 on the recording medium, and the white balance setting information 504 are enlarged and emphasized.

  Further, in the display data 500, it is possible to add explanatory characters for each item by reducing display items. The explanatory characters for each item include, for example, “MANUAL MODE” which is setting information of the display mode dial 133, “CF-CARD” indicating the type of recording medium, WB indicating white balance, and “BATTERY MARK” indicating the remaining battery level. Etc. In the display data 500, two colors are used, and the difference in luminance is high. Such display data 500 makes it easier to read characters and icons even when the backlight illumination 126 is turned off.

  In the present embodiment, the display device 15 is configured to assume power supply by a battery, but there is no problem even if it is configured using sunlight or other spontaneous energy as a power source.

  In the present embodiment, the display device 15 or the electronic imaging device 100 is assumed to have a configuration in which a program and display data are provided in a nonvolatile memory, but a hard disk, a DVD-ROM, a CD-ROM, or the like. There is no problem as a configuration.

  In the present embodiment, the electronic imaging apparatus 100 is configured to assume a lens-exchangeable digital camera, but there is no problem even if it is configured as a compact digital camera integrated with a lens.

  The recording medium is not only a memory card such as a PCMCIA card or compact flash (registered trademark), a hard disk, but also a micro DAT, a magneto-optical disk, an optical disk such as a CD-R or CD-WR, and a phase change type such as a DVD. There is no problem even if it is composed of an optical disk or the like.

  Further, the external removable memory 29 may be configured to be connectable to a plurality of arbitrary numbers.

  In the present embodiment, the recording medium is mounted on the electronic imaging apparatus 100. However, the recording medium may have a single or a plurality of combinations.

  In this embodiment, the camera control circuit 140 and the system control circuit 120 have independent circuit configurations. However, there is no problem even if the system control circuit 120 has the camera control means.

  In the present embodiment, the display data when the backlight illumination 126 is turned off is generated based on the configuration of display data prepared in advance in the system control circuit 120. However, there is no problem even if the user arbitrarily selects the configuration of the display data by setting items on the menu.

  Any of the processes, functions, and the like described in the above embodiments can be realized by a computer-readable program or the like.

  In this case, the processes, functions, and the like described in the above embodiments are realized when a computer (CPU, MPU, or the like) included in the system or apparatus executes the above programs. In other words, the above-described program or the like causes the computer included in the system or apparatus to execute the processes and functions described in the above-described embodiment. In this case, the above-described program or the like is provided to a computer included in the system or apparatus via a computer-readable storage medium or a network.

  A magnetic disk, an optical disk, a magneto-optical disk, a hard disk, a magnetic tape, a nonvolatile memory, or the like can be used as a storage medium that provides the above-described program or the like to a computer included in the system or apparatus.

  Moreover, you may comprise a part of said program etc. using OS (operating system) etc. which are operate | moving on the computer.

  Furthermore, a part of the above-described program may be executed by a function expansion board inserted into the computer or a function expansion unit connected to the computer.

It is a block diagram which shows the internal structure of the display apparatus which concerns on embodiment of this invention. 3 is a flowchart of a liquid crystal display control process executed by the system control circuit 1 in FIG. It is a flowchart of the modification of the liquid crystal display control process of FIG. It is a block diagram which shows the structure of the electronic imaging device which has a display apparatus which concerns on the 2nd Embodiment of this invention. 5 is a flowchart of control processing executed by the system control circuit 120 in FIG. 5 is a flowchart of control processing executed by the system control circuit 120 in FIG. It is a flowchart of the sleep mode process of step S123 of FIG. 5A and 5B are diagrams illustrating display data of photographing conditions in the electronic imaging apparatus 100 of FIG. 4, where FIG. 5A illustrates when the backlight illumination 126 is turned on, and FIG. 5B illustrates when the backlight illumination 126 is turned off.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 System control circuit 2 Power switch 5 Operation member 6 Timer control part 7 Image display process part 8 Liquid crystal drive circuit 9 Liquid crystal panel display element 10 Illumination brightness change circuit 11 Backlight illumination 15 Display apparatus

Claims (7)

In a display device comprising display means for displaying display data, and illumination means for illuminating the display means,
Control means for controlling the lighting means to at least turn on or off;
The display means includes display control means for controlling to display first display data when the illumination means is turned on and to display second display data when the illumination means is turned off,
The second display data, the less number of gradations than the first display data, Ri Oh display data difference in luminance is large between the background color and the character, the second display data, the 1 It reduces the number of items to be displayed than the display data, the display device comprising that you have been added description character items. Before Symbol display items displayed in the second display data display device according to claim 1, wherein the first display item by remote display size is displayed in the display data is larger. It said display control means display device according to claim 1 or 2, wherein the controller controls to use a different color palettes between the first display data and said second display data. The display device, a display device according to any one of claims 1 to 3, characterized in that a display device of an image pickup apparatus having image pickup means. A display step for displaying the display data on the display means;
An illumination step of illuminating the display means with illumination means;
A control step for controlling the lighting means to at least turn on or off;
A display control step for controlling the display means to display first display data when the illumination means is turned on and to display second display data when the illumination means is turned off;
The second display data, the less number of gradations than the first display data, Ri Oh display data difference in luminance is large between the background color and the character, the second display data, the 1 how to the number of items to be displayed than the display data is reduced, it characterized that you have been added description character items. A computer-readable program for causing a computer to execute the display method according to claim 5 . A computer-readable storage medium storing the program according to claim 6 .

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